DE20218101U1 - Radome antenna mount for sector antennas has integral triangular section build - Google Patents

Abstract

A radome antenna (4) mount has a three arm bent support web (1) protruding from the corners of a triangular mast core (2) with the thin glass fibre radome (6) supported by stiffening rings (5.1) attached to stiffening plates (5.2).

Description

Covered antenna carrier

The invention relates to a statically and electrically optimized self-supporting antenna carrier that is tubular in its external appearance for accommodating antennas and technical components.

The mounted antennas and their system technology should not be easily identified as antennas or antenna systems.

Antenna systems are constructed site-specifically according to central or regional specifications.

Since the required antenna heights in inner cities are in most cases at least 15 m, antenna locations are mainly multi-storey residential buildings with gable or flat roofs.
These roofs are usually designed to withstand snow, wind and human loads and are therefore not suitable for supporting larger additional loads.

The further expansion of mobile networks will result in increased use of existing mast systems. This means

• Increased weight due to larger steel cross-sections and
larger wind attack surfaces,

• larger moments of force at the mast base and thus

• the need to introduce forces into the load-bearing walls of the buildings.

The following independent mast systems have become known from the latest state of the art technology for the expansion of mobile phone networks.

EP 1 198 024 A1 describes an antenna mast whose support is designed as a cylindrical hollow body. This hollow body contains an internal structure with supporting parts for antennas and guides on which the antennas can be moved in height. The supporting tube of the antenna mast, which also serves as a covering for the antenna systems and the

associated system components, consists of a non-conductive material at least in the part in which the antennas are in the operating position.

The subject of US 5,995,063 is a tubular antenna mast whose internal structure has a three-beam cross-section. Three vertically movable lifting mechanisms for the antenna modules are attached to this internal structure, arranged offset by 120°.

DE 202 05 549.3 U1 discloses a tubular antenna mast in which, in addition to the multi-part, single-walled or double-walled support tube, a three-beam slat reinforcement is present as an internal structure. The antennas are attached to this slat reinforcement, whose three radially running slats extend as wall reinforcements over the entire length of the antenna support - also vertically movable.

In all known solutions for the design of antenna supports, in addition to a metallic inner structure, separate support tubes are used that enclose the inner structure and, in addition to the cladding function, also take on the task of static stabilization of the mast construction.

They are therefore constructed accordingly solidly with thick walls.

In the case that the internal construction is designed as a three-armed spider, the rays or arms run radially straight, which results in spatial disadvantages for the arrangement of the antennas when divided into 120° sectors between the spider arms.

Based on this state of the art, it is the object of the invention to further develop the structure of the antenna carrier - in interaction with the antennas - with regard to a space-saving internal construction and a cladding of the antenna mast with the smallest possible wall thickness.

An inventive solution to this problem is specified in claims 1 and 4. Further developments of the invention are characterized in the subclaims.

According to the concept of the invention, the internal construction of the new antenna carrier consists of a triangular mast core, on the central axis of which three spider arms are attached, which, starting from this common axis, run radially through the corners of the triangular mast core in a star shape.

The design of the three-armed spider is limited to the length of the antenna carrier without the antenna area, i.e. the three-armed spider is not present in the area where the antennas are in the operating position. This means that the metallic spider arms have no influence on the radiation properties of the antennas.

It is essential for the design of the spider arms that they are angled in the radial direction. The angle of the bend occurs approximately in the middle of their radial length. The angle of the bend is approximately 45°.
The described bending of the radial spider arms leads to a not inconsiderable gain in space, so that larger antennas can be installed with the same mast diameter or a desired horizontal rotation of the antennas by ± 10° can be achieved.

According to the invention, the cylindrical covering of the antenna carrier is carried out by wrapping it with a GRP material in such a way that a GRP covering is applied on the ends of the spider arms, which have additional support surfaces for this purpose. The shape stabilization of the comparatively thin GRP covering is achieved by the additional support surfaces adapted to the curvature.

The following additional support surfaces can be provided at the ends of the spider arms:

· concentric stiffening rings, which are attached at regular intervals with their 360° circumference line to the three spider arms and

• stiffening plates arranged between the stiffening rings on all spider arms, which are attached to only one spider arm at a time with a circumferential angle of approximately 15° and here extend the support surface in the circumferential direction of the cladding.

The following main advantages should be pointed out with regard to the present invention.

With the new internal structure with angled spider arms, the antennas can be swiveled at an angle of about ± 10° in the horizontal plane compared to an internal structure with straight spider arms. When attaching the cover of the antenna carrier, there are the following advantages compared to inserting the internal structure into a stable cover cylinder:

· By wrapping, there are no tolerance requirements between the inner diameter of the cylinder cladding and the outer diameter of the inner structure, which are critical when inserting the inner structure into a prefabricated cylinder, especially for longer cylinder lengths.

· The wall thickness of the cylindrical casing can be very thin.

Therefore, the cladding does not affect the electrical properties of the antennas behind it. The data contained in the data sheets of the antennas used can be used as a basis for planning the radio network.
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For further explanation of the invention reference is made to the patent claims.

Details, features and advantages of the invention will become apparent from the following description of embodiments.
In the accompanying drawing

Fig. 1 Cross-sectional view of a three-armed spider with straight arms (status
of the technique),

Fig. 2 Cross-sectional view of a three-armed spider with bent arms,

Fig. 3 Internal construction with wrapped cladding (longitudinal section,
Cross-section)

Fig. 1 shows a sectional view of a three-armed spider 1 with a central axis 1.1 according to the state of the art. The antennas 4 and the associated remote control unit (RCU) 4.1 are arranged between the straight spider arms 1 in the three 120° sectors thus formed.

The antenna technology used in Fig. 1 and 2 was chosen as an example:

- Antenna 4 - KATHREIN 742 212
-RCU 4.1 - KATHREIN 860 10003

Fig. 2 shows in direct comparison - with the same outer diameter D of the antenna carrier 3 - the inventive design of the inner construction with angled spider arms 1.
After comparing Fig. 1 and Fig. 2, it becomes obvious that the inventive design of the internal construction according to Fig. 2 results in significant space advantages.

Assuming the same diameter D for the antenna carrier 3, this means that in the state-of-the-art solution in Fig. 1, there is no horizontal rotation of the antenna 4 and the associated RCU 4.1 in the individual 120° sectors.

The internal construction according to the invention with three-sided mast core 2 and angled spider arms 1 according to Fig. 2 allows horizontal rotation

at an angle φ = φ ₀ ± Δ φ by about ±10°.
35

The subject of Fig. 3 is an embodiment of the new antenna carrier 3 with inner construction 1, 2 according to Fig. 2 and a cylindrical covering 6, which is applied to the ends of the spider arms 1 by wrapping with a GRP material.

For this purpose, additional support surfaces 5 are provided at the ends of the spider arms 1, which have a curvature corresponding to the radial distance and thus serve to stabilize the shape of the cylindrical shell made of GRP material.

Concentric stiffening rings 5.1 are provided as support surfaces 5, which are attached to the spider 1 at regular intervals and ensure a circumferential 360° support of the GRP material.

Between the stiffening rings 5.1, stiffening plates 5.2 ensure limited support and shape stabilization. These stiffening plates 5.2 are attached in the circumferential direction of the cladding 6 at the ends of the three spider arms 1 and each provide support at a circumferential angle of approximately 15°, see the representation of the cross section A-A in Fig. 3.

The GRP cladding 6 in an exemplary design has a wall thickness of approximately 1.8 mm.

In the example shown, the width of the stiffening rings 5.1 is 80 mm and their distance from each other is approximately 500 mm.

Above the antennas 4, the stiffening ring 5.1 is attached directly to the mast core (not shown in Fig. 3).

To enable the height of the antennas 4 and their associated RCU 4.1 to be adjusted, a guide rail 7 is attached to each side of the three-sided mast core 2.

The antennas 4 are arranged on the guide rail 7 by means of a corresponding suspension such that their radial distance A (see Fig. 2) can be adjusted for electrical optimization of the antenna function.

List of reference symbols

1 Spider, spider arm 1.1 central axis

2 Mast core

3 antenna supports

4 antennas

4.1 RCU (remote control unit)

5 support surfaces

5.1 Stiffening rings

5.2 Stiffening plates

6 GRP material, cladding

7 Guide rail

Claims (6)

1. Covered antenna carrier for receiving sector antennas of mobile radio, consisting of a metallic inner structure which is designed as a three-armed spider ( 1 ) and a dielectric covering at least in the antenna area, characterized in that the spider arms ( 1 ) are angled in the radial direction and engage a triangular mast core ( 2 ) in such a way that they run radially through the corners of the triangular mast core ( 2 ) starting from the common central axis ( 1.1 ) in a star shape. 2. Antenna carrier according to claim 1, characterized in that the bending of the spider arms ( 1 ) occurs approximately in the middle of their radial length and the bending angle is approximately 45°. 3. Antenna carrier according to claim 1 or 2, characterized in that the region in which the antennas ( 4 ) are in the operating position is excluded from the longitudinal extension of the three-armed spider ( 1 ) over the length of the antenna carrier ( 3 ). 4. Covered antenna carrier for receiving sector antennas of mobile radio, consisting of a metallic inner structure, which is designed as a three-armed spider ( 1 ), and a dielectric covering at least in the antenna area, characterized in that the covering is made by wrapping with a comparatively thin GRP material ( 6 ) which rests on the ends of the spider arms ( 1 ), which for this purpose have additional support surfaces ( 5 ) for stabilizing the shape of the covering. 5. Antenna support according to claim 4, characterized in that the support surfaces ( 5 ) have the curvature corresponding to the radial distance. 6. Antenna support according to claim 4 or 5, characterized in that the support surfaces ( 5 ) are designed as concentric stiffening rings ( 5.1 ) which are attached at regular intervals with their 360° circumferential line to the three spider arms ( 1 ), and stiffening plates are arranged between the stiffening rings ( 5.1 ) on all spider arms ( 1 ), which are fastened in the circumferential direction with a circumferential angle of approximately 15° to only one spider arm ( 1 ).