EP1606855A1

EP1606855A1 - Antenna system provided with a radome, damping device and a service area

Info

Publication number: EP1606855A1
Application number: EP04741221A
Authority: EP
Inventors: Maximilian GÖTTL; Wolfgang Mummert; Walter Staniszewski
Original assignee: Kathrein Werke KG
Current assignee: Kathrein SE
Priority date: 2003-08-06
Filing date: 2004-07-22
Publication date: 2005-12-21
Anticipated expiration: 2024-07-22
Also published as: KR101100977B1; TW200507339A; DE502004002676D1; DE10336073A1; CN2699491Y; EP1606855B1; TWI335103B; KR20060041167A; ATE352107T1; ES2279397T3; WO2005018042A1; BRPI0412998A

Abstract

The invention relates to an improved design antenna system (1) characterised in that it is subdivided at least into one top antenna segment (3) provided with bearing core, active antennas and a radome, and at least one lower antenna segment (5) which is axially downwards extended, designed in the form of a service area (5.1) and provided with at least one opening for access into the internal space thereof. Said radome is supported and elastically fixed above at least two damping systems and /or devices which are axially remote with respect to each other.

Description

_ANTENNA N _A NO _RD VOLTAGE _MI T RADOM, DAMPING DEVICE AND SERVICE AREA

The invention relates to an antenna arrangement according to the preamble of claim 1.

For example, an article has been published in the customer magazine of Kathreinerke KG (December 1997 edition), which is entitled "New transmitting antenna on the Säntis, Switzerland". It can be seen from this that the transmission systems include transmission antennas for radio, television and mobile radio. The high altitude and the associated extremely low temperatures in winter made it necessary to use a double-walled and heated radome, within which the spotlights are housed.

In addition, comparable antenna devices have become known in principle, which, however, are only intended for base stations for the mobile radio range, and therefore the radome therefore has a considerably smaller diameter than in the prior art mentioned at the outset. Such prior publications have become known, for example, from DE 202 05 550 Ul or DE 202 18 101 Ul. Both prior publications show a central antenna carrier which, according to DE 202 18 101 Ul, can additionally be provided with radially projecting support walls, as a result of which three sectors or 120 'angular regions which are offset from one another in the circumferential direction are formed. In these areas, conventional antenna devices are attached to the antenna mast and are already provided with their own radome, i.e. with their own antenna cover.

The entire arrangement is surrounded by a cladding which is cylindrical in cross section and which, according to DE 202 18 101 Ul, has a single wall or, according to DE 202 05 550 Ul, can also be double-walled, as in the prior art mentioned at the beginning.

The entire construction effort, including the assembly on site, but also the unfriendliness to repair prove to be very disadvantageous in the latter antenna systems. Particularly if, for example, components are not only to be replaced, but also to be retrofitted, considerable assembly effort is required in order to first remove the entire cladding, to retrofit the corresponding components at great height, and then to re-attach the cladding after work has been carried out.

A generic device for receiving sector antennas has become known from DE 101 19 612 AI. The antenna arrangement for receiving the sector antennas, which preferably consists of mobile radio antennas, has a hend arranged mast, the upper portion of which has a support piece 3 formed by a tube. It is a mast-shaped, inner support tube. The sector antennas are mounted on the outer circumference of this support tube. For the entire arrangement, consisting of the inner support tube and the sector antennas attached to it, a cladding tube attached to the mast is provided, which is permeable to the electromagnetic radiation. It is the so-called radome. The cladding tube connects continuously to a standpipe, which forms the lower section of the mast. The actual mast thus forms a step transition from the lower standpipe with a larger diameter to the upper tubular wire piece with a thinner diameter, passages being provided on the step transition thus formed, through which the cables leading to the sector antennas are laid.

Since the lower standpipe, which is provided with a larger diameter, connects continuously to the upper cladding tube, the entire antenna arrangement appears to be virtually disguised and hidden.

Nevertheless, this generic state of the art has also shown to be a major disadvantage that, at certain higher wind speeds, the entire antenna mast can swing up in such a way that the radome breaks.

The object of the present invention is therefore to overcome the disadvantages of the prior art and to provide an improved antenna arrangement. The object is achieved according to the features specified in claim 1. Advantageous embodiments of the invention are specified in the subclaims.

In fact, it must be said that it is surprising that the present invention creates a highly stable antenna arrangement which is designed in a mast-like manner, the entire antenna system being covered in an extremely narrow tubular radome. As in other known systems, this radome can preferably have a cylindrical cross section, but can also have any other horizontal cross section, for example n-polygonal, oval-shaped, etc. In addition, the antenna arrangement according to the invention is distinguished in that it has includes a service zone in which all relevant setting and connection measures can be carried out, without having to dismantle the antenna mast as a whole or even remove the radome beforehand in order to access the components underneath.

In addition, the antenna arrangement according to the invention has a damping device which ensures that, given the corresponding wind speed, the antenna structure and, in particular, the radome are prevented from rocking, and thus destruction of the system or parts thereof.

A corresponding solution for this had not yet emerged.

The antenna system according to the invention can be constructed in this way be that below the radome it comprises antenna radiators which, for example, radiate in at least two sectors, preferably in three or more sectors. Any radiator devices can be used that can emit in a wide variety of horizontal widths, for example with a 90 'half-width, a 60-65' half-width, etc.

Simply polarized, dual polarized or circularly polarized antenna elements can be used. So-called x-polarized radiators and radiator groups can also be used, the polarization directions of which are oriented at a +45 'or -45' angle with respect to the horizontal plane or a vertical plane.

The antenna arrangement according to the invention can also include broadband or narrowband antennas and radiators. This structure can be such that the entire antenna arrangement radiates and receives only in one band or in several bands, for example in two bands. The band structure can also be so broadband that it covers, for example, the 1800 MHz band, but for example also the 1900 MHz band (as is customary in the USA) and / or the UMTS band of approximately 2000 MHz.

Due to the antenna arrangement according to the invention and the compact design, it is also possible for the first time to set up such an antenna device as an omnidirectional radiator by means of an appropriate interconnection in the service zone. The radiator elements can preferably be adjusted via a remote-controllable down-tilt device with a different beam angle with respect to the horizontal plane. The so-called service zone is preferably located below all radiator elements. The service zone is preferably constructed in such a way that in the closed state it presents itself as an extension of the radome surrounding the radiator elements. For this purpose, the service zone can comprise a corresponding housing frame at a suitable axial height and with a corresponding diameter, which has openings of sufficiently large size to provide access to the interior. The opening areas can be closed and covered by individual covering caps or by housing shells which are surrounded by the antenna mast overall, which preferably lies at least approximately in the circumferential plane of the radome surrounding the radiating elements, so that the overall surface of a mast-shaped surface is as smooth and continuous as possible from the outside Construction results, without being guessable, whether components are contained in this construction and, if so, which components are accommodated.

The service zone is constructed in such a way that it can be mounted on a stump head at which the necessary antenna cables leading to the antenna device end at an interface formed thereby. In the following, this mast stump is also referred to as mast base, mast base or also as antenna base or antenna base. When the service zone is open, the corresponding intermediate cables can be installed, which creates an electrical connection from the cables ending in the antenna base to the connection points in the upper area of the service zone for the cables leading to the radiators. Any necessary components such as amplifiers etc. can also be accommodated in these service zones. The amplifiers can be, for example so-called TMA's, so-called TMB's, etc. Some of the amplifiers or other circuits that, for example, also develop heat that has to be dissipated to the outside, can be designed and arranged in such a way that a part of the amplifier housing is simultaneously used as a cover cap closure arrangement for the opening in the service zone that these devices can optimally release the heat they produce to the outside (part of the heat-generating devices thus represent part of the outer jacket of the antenna arrangement). Because these amplifiers are now closer to the actual radiators (and no longer in a separate base station), not only does the number of cables that have to be laid from the base station to the radiators decrease, but also that for reduce the antenna arrangement necessary energy performance of the amplifier, for example by a factor of 2. Finally, the power and fiber optic cables used can not only be reduced in number, but also, if necessary, in their necessary diameter cross section. The remote-controlled down-tilt setting devices, for example correspondingly controllable motor units, can also be accommodated in the service zone, for example, which then control the phase shifters located within the radome for setting the different down-tilt angles via a transmission linkage.

If required, however, not only one, but also a second or more service zones arranged axially one above the other can be provided, which can also be retrofitted as independent modules if necessary. In the same way, a single service zone can be provided, which for example has an axially greater height has and thus always creates enough space to accommodate additional components.

The service zone is preferably fixable or detachable via screw connections in such a way that an axial turning movement of the service zone and thus of the mast structure located above it is possible even in a state secured by the screw connection. As a result, the antenna radiators can be aligned accordingly.

Further advantages, details and features of the invention result from the exemplary embodiment shown in the drawings. The individual shows:

Figure 1: an overall view of a mast-shaped antenna according to the invention;

Figure la: a mast-shaped antenna according to the invention without a service zone with a radome (not shown) to illustrate the radiator elements located underneath; Figure 2: a prepared antenna base on which a mast-shaped antenna system is built;

FIG. 3: a representation corresponding to FIG. 1, but with the service zone open and before mounting on the antenna base or antenna base; FIG. 4 shows an exploded view of the antenna arrangement and its essential components in a perspective view directed from top to bottom;

Figure 5: a corresponding exploded view of Figure 4, but from a bottom-up perspective;

FIG. 6: an enlarged perspective detailed illustration to explain the fastening of the service zone on the antenna base;

FIG. 7 shows a representation corresponding to FIG. 7 after the service zone with the mast construction resting thereon has been rotated by an angle;

Figure 8 is a cross-sectional view through the mast construction with the antenna elements seated inside;

Figure 9 is a perspective view of a damping device at the overhead end of the mast structure including the cylindrical radome;

Figure 10 is a cross-sectional view through the overhead cover with the damping device according to the invention for the radome in a modified embodiment;

Figure 11 is a vertical sectional view in the area of the lower end of the radome at the transition to the adjacent service zone;

Figure 12: a modified construction to the representation according to Figure 9, shown in a vertical section;

FIG. 13: an exemplary embodiment of a fully assembled antenna arrangement, comparable to FIG. 1, with opened cover covers to illustrate installed modules;

FIG. 14: a further exemplary embodiment to illustrate the additional addition of a further service zone; and

Figure 15: another modified embodiment with a mast-shaped antenna base, which has a smaller outer diameter to the remaining antenna arrangement.

In FIG. 1, an antenna arrangement 1 according to the invention is shown in a schematic perspective illustration, as can be considered in particular as a mobile radio antenna for a base station.

The antenna arrangement 1 comprises an overhead antenna section 3 and at least one further, under subsequent antenna section 5, which comprises at least one service zone 5.1.

The entire arrangement of the upper and axially adjoining lower antenna section 3, 5 is constructed and fastened on an antenna stand device 7, which serves as antenna base 7. This antenna base 7 does not necessarily have to have the mast-shaped design shown in FIGS. 1 ff., But can also have a larger or smaller diameter or a different cross-sectional shape or can also be designed, for example, as a connection point lying at the level of the ground, on which the antenna arrangement is then based 1 is mounted with the at least upper antenna section 3 and the at least one lower antenna section 5.

In FIG. 1 a, the antenna section 3 is shown with the radome 41 partially omitted in order to show the radiators 6 located underneath it, which in the exemplary embodiment shown are each arranged in a plurality of columns offset in the circumferential direction and vertically offset one above the other.

FIG. 2 shows the cylindrical antenna base 7 in the present case, which is generally created on site. This antenna base is firmly anchored to or in the ground. The connection lines 11 required for the operation of the antenna are routed through this antenna base itself, which preferably end in the region of the upper end of the antenna base 7 and are preferably provided with a connection unit, in particular a connection plug-in connection unit 13 there. These connector plugs 13 are held by a holding and strain relief device 15 in the region of the upper end of the antenna base 7 provided with an outlet, passage or access opening 17.

In this respect, the upper end of the antenna base 7 explained can also be understood as an interface 19, on which the antenna arrangement 1, which is usually prefabricated by the manufacturer, is then mechanically placed directly and firmly connected to the antenna base 7 (FIG. 3).

In the exemplary embodiment, the cross-sectional shape and cross-sectional size in the region of the antenna base 7, the explained lower antenna section 5 with the at least one service zone 5.1 provided there and the upper antenna section 3 are the same or substantially the same. In other words, in the present case the diameter is circular and the external dimensions are at least of the same order of magnitude, i.e. in the present exemplary embodiment, less than 20%, in particular less than 10% and above all less than 5% should deviate from one another. This gives the impression of a continuous mast construction, without it being immediately apparent what function this mast serves and whether certain components are housed inside.

4 shows the essential components of the antenna arrangement. between the antenna base 7 and the lower part of the upper antenna section 3 in an exploded view (with a viewing angle directed more from top to bottom) and in FIG. shown angle, which is rather directed from bottom to top. It can be seen from this that the illustrated service zone 5.1 in the exemplary embodiment shown is cylindrical in shape, specifically with an upper and a lower end or connection side 5.1 a and 5.1 b.

With the connection point 5.1 b located below, the service zone 5.1 can be firmly connected by means of screws 25 to the upward-facing connection side 7.1 of the antenna base 7.

Likewise, a connection side 3.1 is provided on the underside of the upper antenna section 3, via which a fixed mounting of the upper antenna section 3 on the lower antenna section 5 located below can also preferably be achieved again by means of a screw connection 27. The screw connections mentioned for the firm connection of the underside 3.1 of the upper antenna section 3 to the service zone 5 are made by screws.

As can be seen from the enlarged detailed illustration according to FIGS. 4 and 5, the connection side 7.1 located at the top has a material ring 7.1 ′ which can be placed on the tubular outer construction of the antenna base 7 or can be part of this tubular antenna base 7. The tubular construction of the antenna base 7 ultimately 3 carries the total weight of the antenna array 1. In order to fix the connection point 7.1 in the circumferential are of ^"direction lying offset a plurality of threaded bores 29 is introduced. The-set-up thereon service zone 5.1 has, for receiving the supporting forces of the upper antenna portion a Construction with one above and one below lying connection ring 5.1 a 'and 5.1 b', which in the exemplary embodiment shown are fixedly connected via three material webs 31 which are offset outwards from the central central axis.

As can be seen from the enlarged sectional view according to FIG. 6, in the embodiment shown, circular elongated holes 33 are installed in the connection ring 5.1 b 'located at the bottom, which are dimensioned at least so long that in the elongated hole 33 two according to the angular distance of the threaded bore 29 Screws 25 can be screwed into the threaded holes 29 in the connecting ring 7.1a '. The screw heads are supported directly or via washers, for example a common washer 36, on the connection ring 5.1b ', since they have a larger diameter and cannot protrude through the elongated hole 33. In other words, the elongated hole 33 is designed in terms of its width so that only the screw shaft of the screws 25 can penetrate this elongated hole 33. Since in the present case the service zone 5.1 has three material webs 31 which are offset at the same angular distance in the circumferential direction, this creates three radial access openings 35, the meaning of which will be discussed below. In accordance with this design, three elongated holes 33, which are seated in the circumferential direction in the region of the respective access opening 35, are also formed in the connection ring 5.1 b 'located below. These elongated holes serve to ultimately be able to secure the antenna in different angular orientations. This is because, for example, the screw 25 ′ located in the slot on the left can be loosened and removed in each slot, the screw 25 ″ located in the slot on the right only being opened slightly becomes. In this position, the service zone 5.1 can then be rotated counterclockwise, for example, about its vertical central axis 26 along the arrow representation 28 until the screw 25 "penetrating the elongated hole at the right end then comes to rest on the left end of the elongated hole 33 (FIG. 7 A new screw can be screwed into the free thread on the right in slot 33 and the screw on the left can be removed so that the entire mast can be completely rotated about its vertical central axis 26 in a secured position.

The supporting structure of the upper antenna section 3 is discussed below.

As can be seen in particular from the cross-sectional illustration according to FIG. 8, the upper antenna section has a central support core 39, which in the exemplary embodiment shown is preferably triangular in cross-section, with webs or ribs running radially outward on the corner regions of this cross-sectionally triangular construction 40 connect. However, these ribs or webs are not absolutely necessary. They can also be omitted or replaced by other design measures. This support core 39 can be made from any material, for example from metal (under certain circumstances also as a continuous casting), from plastic or, for example, from fiberglass, etc. In principle, a very wide variety of materials can be considered. The radiators 6 are arranged offset one above the other in the vertical direction between the ribs 40.

The webs projecting radially outward close then on the radome 41, which has a cylindrical shape in the exemplary embodiment shown. The radome consists of a material which allows the electromagnetic waves to pass through, preferably without any damping or only with little or minimal damping. Fiberglass is a suitable material for this. The support core 39 and the radome 41 can also be formed in one piece, that is to say they consist entirely of material, preferably fiberglass, which allows the electromagnetic waves to pass through. The radome 41 can, however, also be separated from the inner support core 39, in which case projections or grooves are preferably provided on the inner circumferential surface of the radome 41 in the region of the radially outward ends of the mentioned ribs or webs 40, by means of which the radome 41 is held against rotation , In order to avoid an inadmissible rocking that could destroy the entire arrangement at certain wind speeds, the upper antenna section 3 is designed in such a way that the radome 41 is held in place by a damping arrangement 43 located at the top and at the bottom with a presettable or predefinable force with the interposition of a damping device 45.

In FIG. 9, for example, the upper end of this construction is shown in an exploded, exploded view. It can be seen from this that in the triangular construction of the support core 39, three vertical bores 39 'are provided, through which pull rods 39 "are passed using spacers, the spacers serving to ensure that the pull rods 39" do not match the inner wall of FIG Bore 39 'act alternately or can strike against it. 9 shows two of the longitudinal holes 39 ' is still shown without the tie rod 39 "inserted. Only in the hole 39 'at the front in FIG. 9 is a tie rod 39" already inserted, which still protrudes axially upward, that is to say has not yet been fully inserted into the bore 39'. The damping device 45 shown in FIG. 9, which is preferably made of an elastomeric material and is part of the damping arrangement 43, is then placed on the front upper end of this construction. The damping device 45 surrounds at least the upper edge 41a of the radome 41, as shown in the sectional view according to FIG. in that screws 48 are screwed through corresponding bores 47 in the upper cover-shaped pressure transducer 43, which are screwed into end bores of the mentioned tie rods 39 ″, which penetrate the bores 39 ′ in the support core 39.

In the construction according to FIGS. 9 and 10, the entire cover-shaped pressure transducer 46 is by means of a correspondingly shaped damping device 45 not only with the cylindrical radome 41 on the outside, but also with the inner support core 39 including the webs 40 leading outwards via the damping device 45 pressurized, which is why the damping device 45, ie the corresponding damper element, comprises an annular section 45a which can be placed on the upper edge of the radome, three radially inwardly running sections 45b which are offset in the circumferential direction (below which the webs 40 of the support core lie come) and in the middle has a single or multiple articulated damping section 45c, in which bores or extinguishers 45d are also introduced at the locations below which the bores 39 'lie in the support core 39. Therefore, the bores 39 '- in the support core with the openings 45d of the damping device 45 and the bores 47 in the cover-shaped pressure sensor 46, so that the screws 48 (FIG. 9) mentioned above can be screwed in through the passage openings and bores mentioned, specifically into the front internal thread in the .. tie rods 39 "passing through the bores 39 '. In this respect, the damping device 45. can be formed in one piece or in one piece or in several parts on each end face for damping holding of the radome 41.

The construction on the underside is corresponding (FIG. 11). Overall, the construction is chosen so that in certain areas, by tightening the screws 48 mentioned, a pre-tensioning of the damping material lying in a predefined range is achieved, which, even at correspondingly high wind speeds, brings about the desired damping of the entire construction and, as a result, a rocking that destroys the system as a whole safely prevented.

In contrast to FIG. 9, FIG. 12 only shows that the damping device 45 basically only has to be provided on the upper and lower edge region of the radome 41, and that the cover-shaped pressure sensor 43 in the exemplary embodiment shown can rest firmly on the support core 39 , The attachment of the lower cover-shaped pressure sensor 43 'is in principle comparable to the above-mentioned cover-shaped pressure sensor, the main difference being that in the case of the lower cover sensor this has further through openings 50 through which the corresponding connection cables and actuating devices from the Service zone 5.1 can be guided into the interior within the radome 41 in the upper antenna section 3. In other words, a large number of screws are screwed in from the bottom in the vertical direction through corresponding bores in the upper connecting ring 5.1 a 'of the service zone carrier 5', specifically in threaded bores 49 which run from below in the vertical direction on the downward-facing connection side 3.1 are introduced. This ensures a firm connection between the upper and lower antenna sections 3, 5.

In the service zone 5.1, the access openings 35 can now be used to easily install the components that may be required there, to replace them during repair work, or to retrofit other components. Thus, in the exemplary embodiment shown in FIG. 13, three units 51 are shown which can represent, for example, amplifiers (TMA or TMB) or, for example, so-called RET units, which can be used for the remote-controllable setting and changing of the down-tilt angle. Such units can then be used, for example, to actuate an adjustment mechanism which adjusts the phase shifters located below the radome to produce the desired phase shifts in such a way that the desired down-tilt angle can be set. It is about this Functional principle, reference is made to the previously published solutions according to WO 02/061877 A2 and WO 01/13459 AI, which are made the content of the present application.

It can also be seen from FIG. 14 that the antenna arrangement can in principle be supplemented by further service zones 5.2 etc. All service zones are preferred - even if they differ in their axial length - at least with regard to their connection sides located at the top and bottom, so that, for example according to FIG. 14, a further service zone 5.2 can be interposed axially.

Since, with the covers 53 removed, by means of which the access opening 35 can basically be closed, there is free access to the interior 36 in the area of the one or more service zones, a connection can be made from there as desired to the connection ends of the cables ending there on the underside of the upper antenna section 3 are further connection points which are made there to the individual radiating elements or phase shifters etc. If required, any electrical / electronic modules can be interposed, repaired, replaced or retrofitted.

In Figure 1, a cover 51 'is indicated in the service zone 5.1. This can be a removable and / or, for example, a cover, preferably pivotable outward about a vertical axis of rotation, in order to provide free access to the service zone. However, the cover can also be simultaneously through a housing wall of a built-in module 51. As a result, the heat generated by the module can be dissipated to the outside particularly well.

This cover 51 'can be smaller than the total opening to the interior 36 of the service zone. Therefore, the cover can also be formed in two parts, namely include a cover frame, in which an opening is again made, in which the housing wall of the module then comes to rest as the cover end side.

With reference to FIG. 15, it is only shown in principle that the antenna base 7 can also be designed differently in terms of its shape or dimensions, that is to say it is provided with a small diameter in this exemplary embodiment. This possibly offers the possibility of leading cables up the outside of such a mast-shaped antenna base 7 and then leading them from below into the interior space 36 into the service zone 5 on the underside of the first service zone 5.1 adjoining them.

Claims

claims:

1. Antenna arrangement with the following features: the antenna arrangement has a support core (39), the support core (39) is surrounded by a radome (41), between the support core (39) and the radome (41) are radiators for receiving and / or Transmitting arranged, characterized by the following further features: the antenna arrangement (1) is at least in an upper antenna section (3) with the support core (39), radiators and the radome (41) and at least one axially below the lower antenna section (5) structured, the lower antenna section (5) is equipped as a service zone (5.1), which has at least one circumferential access opening (35) to the interior (36) in the service zone (5.1), and the radome (41) is at least two damping arrangements (43) offset in the axial direction and / or damping devices (45) offset in relation to one another are held and anchored elastically.

2. Antenna arrangement according to claim 1, characterized in that the damping device (45) bears at least in sections on the upper edge and / or on the lower edge of the radome (41) on its outer circumference.

3. Antenna arrangement according to claim 1 or 2, characterized in that the damping device (45) bears at least in sections on the upper edge and / or on the lower edge of the radome (41) on its inner circumference.

4. Antenna arrangement according to one of claims 1 to 3, characterized in that the damping device (45) at the upper end of the radome (41) on the upward face of the radome (41) and / or at the lower end of the radome (41) rests on the downward face of the radome (41).

5. Antenna arrangement according to one of claims 1 to 4, characterized in that the damping device (45) bears against the radome (41) under prestress.

6. Antenna arrangement according to one of claims 1 to 5, characterized in that the damping element completely overlaps the end face of the upper and / or lower edge of the radome (41).

7. Antenna arrangement according to claim 6, characterized in that the damping material bears against the radome (41) under pre-compression or pre-tension.

8. Antenna arrangement according to claim 7, characterized in that the damping device (45) is held pressed against the radome (41) under preselectable prestress.

9. Antenna arrangement according to one of claims 1 to 8, characterized in that a pressure sensor (46) is provided on the upper and / or lower edge of the radome (41), which pressurizes the upper and / or lower end of the radome (41), preferably with a presettable prestress with the interposition of the damping device (46).

10. Antenna arrangement according to claim 9, characterized in that the pressure transducer (46) provided on the upper and / or lower end of the radome (41) has support shoulders on which the damping device (45) is supported and pretensioning forces in the damping device (45). generated which act on the adjacent outer circumference, on the inner circumference and / or in the axial direction on the associated end face of the radome (41).

11. Antenna arrangement according to one of claims 7 to 10, characterized in that the damping device (45) is further provided between the pressure sensor (46) and the support core (39) inside the radome (41).

12. Antenna arrangement according to one of claims 7 to 11, characterized in that the damping device (45) is further provided between the pressure sensor (46) and the webs (40) extending between the support core (39) and the inside of the radome (41) ,

13. Antenna arrangement according to one of claims 1 to 12, characterized in that the pressure sensor (46) in the direction of the support core (39) can be biased.

14. Antenna arrangement according to one of claims 1 to 13, characterized in that the radome with its opposite end faces between an upper and a lower pressure sensor (46) with the interposition of each because a damping device (45) is held elastically pretensioned, these upper and lower pressure transducers (46) being able to be tensioned towards one another, preferably via one or more tie rods (39 ") running between the two pressure transducers (46).

15. Antenna arrangement according to one of claims 1 to 14, characterized in that the service zone (5) is designed as a carrier (5 ') which is at least indirectly fixed to the underside of the upper antenna arrangement (3) on its upper end face (5.1 a) is connected or connectable, and that the carrier (5 ') can be mounted on an antenna base (7) on its front underside (5.1 b).

16. Antenna arrangement according to one of claims 1 to 15, characterized in that preferably in the circumferential direction at least two, preferably at least three openings (35) are formed in the carrier (5 ') serving as service zone (5), which can be closed ,

17. Antenna arrangement according to claim 16, characterized in that the openings (35) can be closed via a lid.

18. Antenna arrangement according to claim 16, characterized in that the opening (35) can be closed by modules (51) provided in the interior (36) of the service zone (35) or mounted there, so that at least part of the housing wall of a module serves as a closure cover for the opening (35) in the service zone (5) serves.

19. Antenna arrangement according to one of claims 1 to 18, characterized in that the lower forehead and Mon- day is formed on the upper antenna arrangement by the pressure transducer (46) arranged below.

20. Antenna arrangement according to one of claims 1 to 19, characterized in that in the area of the service zone (5; 5.1, 5.2) in the interior space (36) provided there, the connection ends and / or the connection points or plugs of the cables end, on the one hand are supplied via the antenna base (7), and furthermore, in the area of the service zone (5; 5.1, 5.2) in the interior space (36) provided there, the connection ends and / or the connection points or plugs of the cables which end in the guide the upper antenna section (3) housed radiators, and that these connection ends and / or connection points or plugs of the cables and lines in question in the area of the service zone (5) can be connected via electrical modules and structural units located there or directly via connecting cables.

21. Antenna arrangement according to one of claims 1 to 20, characterized in that the cables or cable ends laid through the base station (7) are held and anchored by strain relief devices.

22. Antenna arrangement according to one of claims 1 to 21, characterized in that the service zone consists of a carrier with an upper and a lower support plate, the upper end face having a central section which serves as a support section for the support core (39).

23. Antenna arrangement according to one of claims 1 to 22, characterized in that the carrier (5) of the service ne (5) has a central average opening on its lower end face.

24. Antenna arrangement according to one of claims 1 to 23, characterized in that the service zone (5) consists of one or more axially one above the other carriers (5.1, 5.2) which are axially fixable to each other.

25. Antenna arrangement according to one of claims 1 to 24, characterized in that the carrier of the service zone (5) is preferably provided on its lower support end face with elongated holes (33) which are offset in the circumferential direction, preferably part-circular elongated holes (33), the length of which are dimensioned so long that at least two screws (25) which are offset in the circumferential direction penetrate the elongated hole (33) and can be screwed into the support plate of the antenna base (7) below or an end support plate of a further service zone (5, 5.2) located underneath ,

26. Antenna arrangement according to one of claims 1 to 25, characterized in that a wide variety of antenna modules can be accommodated in the interior (36) of the service zone (5), in particular amplifiers (TMA, TMB), remote-expensive units for setting different angles of lowering of the radiator device.