FR2932016A1 - SELF-SUPPORTING ANTENNA FOR BASE STATION AND ASSEMBLY FOR ANTENNA SYSTEM INTEGRATING SUCH ANTENNA. - Google Patents

Abstract

The invention relates to an antenna for a base station of a cellular telephone network, comprising an outer envelope (10) of determined height delimiting a cavity (11) closed by two end walls (121), and in which is provided a reflector device associated with radiating elements, characterized in that the outer casing (10) further comprises stiffening means (14), so that the antenna is self-supporting.

Description

SELF-SUPPORTING ANTENNA FOR BASE STATION AND ASSEMBLY FOR ANTENNA SYSTEM INTEGRATING SUCH ANTENNA. The invention relates to the field of cellular telephony and more particularly to the base stations of a cellular or mobile telephone network. A cellular network comprises a central transceiver at each cell, called a base station. A base station allows the mobile phone to connect to the network to transmit and receive communications. The connection between the mobile phone of the user and the base station is via a radio link. A base station conventionally consists of a relay antenna and an electronic cabinet responsible for the management of communications. The relay antenna is mounted on a mast that must be placed on a raised site to cover as wide an area as possible. Conventionally, an antenna of a base station comprises an outer envelope, commonly referred to as a radome, which is of elongated shape and which delimits a cavity in which a plurality of radiating elements are provided, a distribution system of the energy between the radiating elements and a reflective device. The outer casing may be made of a composite material or alternatively ASA or polycarbonate. The advantage of composite materials is that they have good mechanical strength. However, they are materials that are not very transparent to radio waves. Conversely, ASA and polycarbonate have limited strength properties but are transparent to radio waves. Furthermore, whether or not the antenna installation is pre-assembled before it is put in place, its assembly is complex. This is due to

the multiplicity of elements to handle. This complexity is increased by the sizing of parts. Finally, the analysis of antennas on the market shows that manufacturers have developed, successively, antennas for each particular technology or application. This results in a multiplicity of antennas with congestion and very different profiles. This considerably limits the modularity of the antenna systems and their adaptability, when new antennas must be installed on an existing mast. It is understood that in these antenna systems, the mast is an essential element since it is he who ensures the mechanical strength of the assembly. Antenna systems must withstand high winds, up to 200 km / h, for example. This is why the diameter of the masts can be greater than 600 mm. The importance of this diameter contributes to the visual clutter of conventional antenna systems. The installation of an antenna on a mast requires of course the attachment of it on a mast, but also its orientation in azimuth. This orientation can be imposed by the structure of the network. Many solutions have been proposed to secure the attachment of an antenna to a mast. These fastening systems are sometimes of significant size and require to distance, significantly, the mast antenna. In any case, a relatively large distance must be provided between the mast and the antenna in order to orient the antenna in azimuth. Throughout the present application, the term "mast" means an elongate support, made in particular of metal, intended to be installed so as to extend vertically and carry telecommunication antennas. In addition, it is generally three antennas which are fixed on a mast, substantially at 120 ° to one another.

As a result, the antenna or antennas of a base station are cumbersome and environmental standards impose increasing constraints for their installation. It has been developed camouflage systems intended to cover at least partially the antenna. However, these systems are extremely fragile and have a relatively short life span, given the climatic constraints. In addition, they are not very effective in preserving the environment. This is why it has been proposed antenna systems incorporating the three antennas in a single housing of substantially cylindrical shape. Thus, the document EP-1 606 855 describes an antenna system comprising an upper active part with the antennas and a lower service part.

In the upper part, the antennas and the carrier core are placed in a cylindrical housing or radome. Such a system makes it possible to give a cylindrical shape to the antenna system and thus to limit its visual impact on the environment. However, the azimuth adjustment of each antenna, as well as their maintenance are extremely difficult, if not impossible, because of the presence of this outer housing. Moreover, this case is an additional piece that fulfills only an aesthetic function. Thus, such an antenna system is a much higher cost than that of the elements that compose it. In addition, such a housing can disrupt the operation of the antennas. Finally, such an antenna system must be pre-assembled before being put in place, for example on a roof of a building. However, such a system is bulky and heavy to handle, which makes its implementation extremely complex, especially in urban areas.

The invention therefore has for. to overcome the disadvantages of the state of the art by proposing an antenna which is designed to simplify its installation, even offering the possibility of removing the presence of the support mast, and in any case, by allowing a system antenna comprising one or more antennas according to the invention to limit the visual nuisance in the environment, thanks to its compactness. In addition, this antenna allows the successive installation, on existing base stations, of new antennas for different technologies. Thus, the invention relates to an antenna for a base station of a cellular telephone network, comprising an outer envelope of determined height, delimiting a cavity closed by two end walls, and in which there is provided a reflector device associated with radiating elements. According to the invention, the outer envelope further comprises stiffening means, such that the antenna is self-supporting. This particular structure of the antenna makes it possible to lighten the structure of the mast on which it is fixed, or even to completely remove it. The antenna system according to the invention will therefore be extremely simplified compared to conventional systems. Preferably, the stiffening means are mechanically independent of the reflector device. In conventional antenna systems, the linkage means to the mast are generally connected to the reflector and not to the outer casing 25 of the antenna. This is due to the fact that the reflector is conventionally made of aluminum and has a greater mechanical strength than the envelope itself. This type of fixation makes it possible to use the mechanical strength of the reflector. However, it has a major drawback which is the absence of separation between the electrical and mechanical functions. However, significant differences in expansion can occur, in use, between the reflector and the mast on which the antenna is attached. This

causes significant constraints on the reflector, constraints that can affect the electrical function of the reflector and therefore the reliability of the antenna itself. These disadvantages are avoided when the stiffening means are mechanically independent of the reflector device. Moreover, in conventional antenna systems, the reflector is generally given a weight greater than that strictly necessary for its electrical function. This of course has consequences for the overall weight of the antenna and its manufacturing cost. With the antenna according to the invention, the reflector device can be considerably lightened and the stiffening means do not bring overweight to the antenna. Finally, when the reflector device does not have to provide mechanical function, its design is not limited by constraints related to a high level of mechanical strength. These stiffening means may be integrated into the envelope or reported thereon. Preferably, they extend over substantially the entire height of the antenna. The invention also relates to an assembly for producing an antenna system intended for a base station, this assembly comprising: an antenna as defined above, a mast, and antenna linkage means on the mast, these means being designed to bear on both the end walls of the antenna and the mast, so as to grip the antenna. Thus, such an assembly makes it possible to mount the antenna on a mast of simplified structure, insofar as the antenna itself is self-supporting. In addition, the connecting means do not lead to an increase in the space generated by the antenna and the mast themselves.

Indeed, they are not placed between the antenna and the mast, as in antenna systems according to the state of the art, these connecting means leading to a separation of the antenna and the mast. Thus, an antenna system made from such an assembly 5 has a smaller footprint compared to a conventional antenna system and thus reduces visual nuisances on the environment. The mast may have a shape complementary to that of the antenna, so that after connection between the antenna and the mast, they have a compact external shape. This embodiment further reduces the visual nuisance of an antenna system made from this set. Still for this purpose, the antenna and the mast are designed to have, once bound, a substantially continuous outer shape and rounded. The invention also relates to an assembly for obtaining an antenna system for a base station, said assembly comprising at least two antennas as defined above and connection means designed to bear on the walls of the base station. end of each antenna, so as to grip said at least two antennas and ensure their connection. This set provides an antenna system radically different from those known in the state of the art, since it requires no mast. The removal of such a mast is permitted, since each antenna has stiffening means that make it self-supporting. An antenna system made from such an assembly is therefore particularly compact and its impact on the environment is reduced compared to conventional antenna systems. The shape of the antennas can also be chosen so that, once assembled, they have a continuous and rounded outer shape.

Preferably, the connecting means are substantially planar. Preferably, the connecting means are designed to allow the azimuth orientation of each antenna.

In some cases, and particularly when the antenna system must be placed in a geographical area exposed to high winds, the assembly according to the invention may also comprise a mast, the connecting means then being also designed to be fixed on said mast. When an assembly according to the invention comprises a mast which is part of an already existing installation, the connecting means are segmented. The invention also relates to an assembly for an antenna system for a base station further comprising at least one profile, intended to be mounted between two antennas. Preferably, the height of this profile corresponds substantially to that of the antennas. This profile may have, after assembly of the assembly, two different functions. This profile can firstly have a stiffening function and is particularly useful when groups of complementary antennas 20 must be added above an existing group of antennas. In this case, the profile structure is designed so that it can provide this stiffening function. Such a profile inserted between two antennas, may also have the function of giving the assembly consisting of the antennas and the profile 25 a substantially continuous outer shape and rounded. In this case, the profile does not need to have a significant mechanical strength. It has the effect of reducing the visual annoyance of the antenna system obtained. The invention also relates to an antenna system for a base station of a telephone network, comprising at least one antenna as defined above.

This system may comprise at least two antennas according to the invention, intended for different networks, said at least two antennas being placed at different heights in said system and each antenna being fixed by connecting means bearing at least on the walls end of said antenna, so as to grip it. These networks can be of the WIMAX, GSM, UMTS or PMR type, for example. This antenna system may include a mast. In a conventional embodiment, the antenna installation comprises at least two groups of three antennas, placed at different heights of the system. Preferably, this antenna system comprises at least one profile between two antennas intended for the same network. The invention will be better understood and other objects, advantages and characteristics thereof will appear more clearly on reading the description which follows and which is given in relation to the accompanying drawings which show embodiments of the invention. and in which: - Figure 1 is a schematic sectional view of an antenna according to the invention, - Figure 2 is a side view of an antenna according to the invention being mounted on a mast, - FIG. 3 is a sectional view along the line III-III of FIG. 2; FIG. 4 is a view similar to FIG. 3 which illustrates two extreme positions of the antenna during its azimuth orientation; FIG. 5 illustrates a variant of the mast represented in FIGS. 2 to 4, with a detail A; FIG. 6 shows a system of two antennas according to the invention assembled without a mast and associated with two sections, FIG. cross section, a system of three antennas according to the invention,

FIG. 8 represents an antenna system comprising three groups of antennas, intended for different networks and made from antenna according to the invention; FIG. 9 is a perspective view of a detail of the antenna; FIG. 10 is a cross-section of an antenna system comprising profiles, FIG. 11 is a perspective view of FIG. 12, and FIG. 12 is an alternative embodiment of FIG. For reasons of simplification, the elements common to the different figures will be designated by the same references. Referring firstly to Figure 1, the antenna 1 according to the invention comprises an outer casing 10 or radome which delimits a cavity 11 which is closed by two end walls 12 (shown in Figure 2). Inside this cavity, there is provided a reflector device 13, for radiating elements not shown in Figure 1. The reflector device may consist of a single reflector or a plurality of reflectors. In the cavity 11, stiffening means 14 are also provided. In the example illustrated in FIG. 1, these stiffening means are attached to the outer casing 10 of the antenna. They could also be designed to be directly integrated into the outer envelope. In the example illustrated in FIG. 1, the stiffening means are designed to be able to come into contact with at least a part of the inner wall 100 of the envelope. They comprise two symmetrical elements and which are arranged on either side of the axis of symmetry XX 'of the antenna. The stiffening means are here connected together by end plates (not shown) and are not limited to this exemplary embodiment. 2932016 io

The length of the stiffening means may correspond to the height of the antenna, so as to be the most effective. The reflector device 13 is fixed in the cavity 11, by means of fixing means on the stiffening means 14. This attachment can in particular be made by gluing. This allows slight relative movements between the reflector and the stiffening means. Such movements may in particular be due to differences in expansion between the different elements forming the antenna 1. The mounting of the antenna illustrated in FIG. 1 will now be described with reference to FIGS. 2 and 3. These figures show the antenna 1, a mast 2 and means 3 for connecting the antenna to the mast. These connecting means 3 comprise two elements 3a and 3b. Each of them has a substantially flat portion 30 30, here in the form of wings or open V, and tabs 31 each extending a branch of the V, in a plane substantially perpendicular to the portion 30. In each branch of the V , an aperture 32 is provided. These two tabs enclose an area 33 corresponding to the base of the V and which is intended to come into contact with the mast, as shown in FIG. 3. The element 3a is symmetrical with respect to a ZZ 'axis passing through the center of the wall 32. Each element 3a or 3b is mounted on the mast 2 by any suitable means, in particular by means of a collar. The mounting of the antenna 1 on the mast 2 is carried out as follows. The element 3a is first fixed to the mast 2. The antenna is provided on each of its end walls 12 with two protruding threaded elements 15, one of them being illustrated in FIG. .

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The two elements 15, located on the wall 12 which will be the bottom wall of the antenna once mounted, are then introduced into the two openings 32 of the element 3a. When the antenna is in the vertical position, substantially parallel to the mast 2, retaining means 17, such as nuts, are screwed onto the elements 15 to ensure their retention in the openings 32. As will be seen later, this maintenance does not impede the sliding movement of the elements 15 in the openings 32 of oblong shape. Finally, the connecting element 3b is positioned above the antenna 1, as shown in Figure 3. It is then slid along the mast, in the direction illustrated by the arrow F until that the elements 15, placed on the wall 12 in the upper position after mounting of the antenna, are inserted into the openings 32 of the connecting element 3b. As before, retaining means 17 are then placed on the elements 15 to hold them in the openings 32 while allowing them to slide inside these openings. Of course, the attachment of the connecting elements on the end walls of the antenna could be provided by any other appropriate means. FIG. 4 illustrates two extreme positions of the antenna 1, with respect to the mast 2. These two extreme positions are defined with respect to the median position illustrated in FIG. 3, in which the axis of symmetry XX 'of the antenna coincides with the axis of symmetry ZZ 'of the connecting element 3a. In the position A, the antenna is tilted to the left with respect to the plane of the figure, so that its axis of symmetry XX 'is at an angle with the axis of symmetry ZZ' of the element 3a. In this position, the element 17 located on the left of the figure is in abutment against the bottom 320 of the corresponding opening 32, while the element 17 located on the right side of the figure abuts against the bottom 321. of the opening 32 located on the right side of the figure.

Conversely, when the antenna is in the position B, the element 17 located on the left-hand part of FIG. 4 is located in abutment against the bottom 321 of the opening 32 on the left-hand side, whereas the element 17 located on the right side of Figure 4 abuts against the bottom 320 of the corresponding opening 32 s. In this position B, the axis of symmetry XX 'of the antenna 1, also makes an angle with the axis of symmetry ZZ' of the element 3a. Of course, the antenna 1 can take all the intermediate positions between the positions A and B illustrated in FIG. 4. Moreover, this Io which has just been described for the element 3a and the antenna 1 can be directly transposed to relative movement of the antenna 1 of the element 3b. It is therefore understood that the openings 32 and the sliding mounting of the antenna 1 in the openings 32 allow the azimuth adjustment of the antenna 1. This adjustment is made very simply and without the need to move the antenna away from the mast 2. Reference is now made to FIG. 5 which illustrates an alternative embodiment of the antenna illustrated in FIG. 3. FIG. 5 is a top view of an antenna 1, mounted on a mast 20, via connecting means, an element 4b is illustrated in Figure 5. The mast 20 differs from the mast 2 shown in Figure 3 in that it has not a cylindrical section but a semi section -spherical. In the embodiment illustrated in FIG. 5, the mast 20 comprises an outer envelope 200 delimiting a cavity 201. In the envelope 200, on the wall 202 intended to be placed opposite the antenna 1, there are grooves, here four in number. FIG. 5 shows that, thanks to this particular profile of the mast 20, after assembly of the antenna and the mast, these have a shape which is not only compact but also substantially continuous and rounded. This helps to limit the visual impact of the antenna and the mast on the environment.

The connecting means associated with the antenna 1 and the mast 20 differ from those illustrated in FIG. 3 in that they carry nuts 204 intended to be inserted into the grooves 203. These nuts are, for example, snap nuts. or quarter turn nuts. FIG. 6 illustrates two antennas 1 assembled thanks to connection means according to the invention. Figure 6 is a view similar to Figure 5 which shows, seen from above, two antennas 1 according to the invention which are arranged so that their bottoms 16 are placed opposite. The two antennas 1 are mounted together by means of connection means, of which an element 5b is illustrated in FIG. 6. The connecting element 5b bears on two end walls 12 of the antennas 1. The element 5b is located at the top of the antennas mounted and installed on a base station. The element which is symmetrically arranged on the lower end walls of the two antennas 1 is not visible in FIG. 6. The element 5b is substantially flat and has, in this embodiment example, two axes of symmetry Y1Y1. and Y2Y2 '. After assembly of the antennas and the connecting element 5b and in the middle position 20 of the antennas, the axis of symmetry Y1Y1 'of the element 5b coincides with the axis of symmetry XX' of the antennas, while the axis of symmetry Y2Y2 'of the connecting element 5b constitutes an axis of symmetry between the two antennas 1. The connecting element 5b has a generally rectangular shape, comprising four oblong apertures 52. The openings are symmetrical two by two with respect to the Y1Y1 and Y2Y2 axes. In these openings, can be placed the retaining elements 17 for the projecting elements 15 of each antenna. As explained previously with reference to FIGS. 3 and 4, the cooperation between the retaining means 17 and the openings 52 makes it possible to adjust the azimuth orientation of each antenna 1. This adjustment is carried out for each antenna independently. 10

Of course, after adjusting the azimuth orientation, the axis of symmetry of each antenna may no longer coincide with the axis of symmetry

In the exemplary embodiment illustrated in FIG. 6, the two-antenna system according to the invention also comprises two profiles 50. Each profile has an elongated shape and their height preferably corresponds substantially to that of the two antennae, so as to be able to extend between the connecting means. Of course, the shape of these profiles 50 is chosen to be able to be inserted between the two antennas, without hindering their movement when adjusting their azimuth orientation. As shown in Figure 6, the wall 500, which constitutes the outer wall of the profiles 50 after insertion between the two antennas, has a rounded shape. Thus, thanks to these sections 50, the two-antenna system according to the invention has a substantially continuous and rounded outer shape. As a result, these profiles 50 again make it possible to reduce the visual impact in the environment of the antenna system according to the invention. The example illustrated in FIG. 6 shows that the antenna according to the invention makes it possible to produce a system of two antennas without the need for a mast. This is enabled by the presence of stiffening means provided in the antenna itself, stiffening means that make it self-supporting. Reference is now made to FIG. 7 which illustrates a system of three antennas 1 according to the invention. The three antennas 1 are placed substantially at 120 ° from one another and sandwiched between connecting means which bear on their end faces 12. Each element 6a, 6b of the connecting means has a substantially flat shape and comprises three branches 60, 61 and 62 substantially at 120 ° from each other. On each branch 60, 61 and 62, are 2932016 i5

two openings facing each other 600, 610 and 620. As previously described with regard to FIG. 3, these openings have an oblong shape corresponding to that of the antenna 1, so as to allow the adjustment of the antennas in azimuth . Furthermore, each element of the connection means comprises a central opening 6, in particular for the passage of cables. The three antennas 1 are mounted in such a way that an antenna is connected between two branches of the fixing element 6b. The connection between an antenna and the element 6b is carried out by means of the projecting elements carried by each antenna, openings provided in each branch of the connecting element and retaining means 17, similar to those which have been illustrated previously. Of course, the mounting of the antennas 1 on the connecting element 6a is performed in the same way as for the element 6b. Thus, the system of three antennas according to the invention comprises only three antennas and connection means for their assembly, the holding of the system being provided by the stiffening means provided in each antenna. Figure 7 illustrates how the antennas can be adjusted in azimuth independently of one another. Thus, FIG. 7 illustrates three half-lines a1, a2, a3 each corresponding to an axis of symmetry between two branches of the connecting element 6b. Thus, the half-lines a1, a2, respectively a3 are the axes of symmetry of the legs 60 and 61, 60 and 62, respectively 61 and 62 25 of the fastening element 6b. FIG. 7 shows that the azimuth adjustment of one of the antennas 1 leads to positioning it so that its axis of symmetry coincides with the half-line a2. The orientation of the other two antennas leads to shift their axis of symmetry by an angle a with respect to the axes of symmetry a1, respectively a3.

Of course, FIG. 7 is only an example of the relative positioning of the three antennas resulting from their azimuth orientation. Other relative positions of the antennas of the system illustrated in FIG. 7 can be envisaged, depending on the environment in which the antenna system is installed. In a variant of the embodiment illustrated in FIG. 7, a mast could be provided. Referring now to Figures 8 and 9 which illustrate another antenna system according to the invention. As shown in FIG. 8, this antenna system comprises three groups 80, 81 and 82. In this example, all the antennas are antennas according to the invention. They are therefore self-supporting and the antenna system shown has no mast. Reference 84 denotes a service chest disposed at the bottom of the antenna system. This box 84 is used both to place cables for example and to elevate the antenna system, if this is necessary in view of the environment in which it is placed. This antenna system comprises different antenna groups, each of them being dedicated to a particular technology. Figure 8 shows that an antenna system according to the invention is scalable and can be modified over time to add an additional antenna group. Figure 9 is a perspective view showing the region between the two groups of antennas 80 and 81 shown in Figure 8. The assembly of the antennas illustrated in Figure 8 is performed as follows. First, the group of antennas 80 is assembled thanks to the connecting means 80a and 80b, as has been previously described, in particular with regard to FIG. 7. In the embodiment illustrated in FIGS. 8 and 9, the connecting elements are in the form of a disc and have openings 800 for azimuth adjustment of the antennas independently of one another.

When the base station must be usable for another technology than that corresponding to the first group of antennas 80, a second group of antennas 81 is mounted on the first. For this purpose, interconnection means 85 are placed between the upper link element 80b of the first group 80 and the lower link element 81a of the second group of antennas 81. They are provided to allow access to the elements retaining and therefore the azimuth antenna adjustment. Moreover, they make it possible to adjust the relative positioning of two groups of antennas. The second group of antennas 81 is then mounted, enclosing the three antennas between the connecting elements 81a and 81b. The connecting elements 81a and 81b also have openings 810, through which the antennas can be oriented in azimuth, as shown in FIG. 9.

Finally, if it is also necessary, a third of antennas is mounted on the second group 81, by first placing an interconnection element 86 between the connection elements 81b and 82a. In the same way as described above, the antennas of the third group 82 are thus clamped between the two connecting elements 82a and 82b. Figure 10 illustrates a preferred embodiment of the antenna system shown in Figure 8. Figure 10 is a sectional view showing the three antennas 1 and the lower connecting member 80a. The reference 820 25 designates a cavity made in the connecting element 80a for the passage of cables. It will be understood that the upper connecting element 80b also comprises such a cavity around which the connecting element 85 will be arranged. FIG. 10 shows that between each antenna 1, there is a profile 9. The shape of the profiles 9 is designed not to interfere with the azimuth setting of the antennas. It has a length that can be much greater than the height of the antennas and contributes to reinforcing the mechanical strength of the group of antennas 80. These profiles 9 may be useful in an antenna system such as that illustrated in FIG. 8, having several groups of antennas and thus having a large overall height. Such profiles may also be provided in the other groups of antennas 81 and 82. Referring now to FIGS. 11 and 12 which illustrate an alternative embodiment of FIG. 7. This again is a set of FIGS. three antennas 1 which are mounted on a mast 2, substantially 120 ° (b) from each other. The set of antennas differs from that illustrated in Figure 7, in that the connecting element is segmented. Indeed, instead of being composed of a single element 15 substantially plane, as the element 6b illustrated in Figure 7, the connecting element is here composed of three elements 7b separated from each other. In practice, each of these elements 7b corresponds to an element 3a illustrated in Figure 3. They will therefore not be described in more detail. As already described above, the mounting of each antenna 1 in an element 7b, via the retaining means 17 cooperating with the openings 70, allows the azimuth adjustment of each antenna, independently of the other two. This embodiment of the connecting elements is used when a set of antennas according to the invention is to be mounted on an existing mast. Indeed, in this situation, it is difficult to insert a single element, such as the element 6b, on a mast already installed. It is then preferable to proceed with the individual assembly of three segmented elements 7b. The reference signs inserted after the technical features appearing in the claims are intended only to facilitate the understanding of the latter and can not limit its scope.

Claims (17)

REVENDICATIONS1. Antenna for a base station of a cellular telephone network, comprising an outer envelope (10) of predetermined height, delimiting a cavity (11) closed by two end walls (12), and in which a reflector device is provided ( 13) associated with radiating elements, characterized in that the outer casing (10) further comprises stiffening means (14), so that the antenna is self-supporting. 2. Antenna according to claim 1, characterized in that the stiffening means are mechanically independent of the reflector device. 3. Antenna according to claim 1 or 2, characterized in that the stiffening means are integrated with or reported on the outer casing. 4. An assembly for producing an antenna system for a base station, this assembly comprising: an antenna (1) according to one of claims 1 to 3, - a mast (2, 20), and means for connecting the antenna to the mast, these means being designed to bear on both the end walls of the antenna and the mast. (2), so as to grip the antenna. 25 5. The assembly of claim 4, wherein the mast (20) has a shape complementary to that of the antenna (1), so that after connection between the antenna and the mast, they have an outer shape compact. 6. Assembly for the realization of an antenna system 30 for a base station, this set comprising at least two antennas according to one of claims 1 to 3 and connecting means (5b; 6a, 6b; 7b 80a, 80b; 81a, 81b; 82a, 82b) adapted to bear on the end walls (12) of each antenna (1), so as to grip said at least two antennas and ensure their connection. 7. Assembly according to one of claims 4 to 6, wherein the connecting means are substantially planar. 8. An assembly according to one of claims 4 to 7, wherein the connecting means allow the azimuth orientation of each antenna. 9. Assembly according to one of claims 6 to 8, also comprising a mast (2), the connecting means (6a, 6b, 7b) being also designed to be fixed on said mast. 10. Assembly according to one of claims 6 to 9, wherein the connecting means (7b) are segmented. 11. An assembly according to one of claims 6 to 10, also comprising at least one profile (50, 9) intended to be mounted between two antennas. 12. The assembly of claim 11, wherein the height of the profile corresponds substantially to that of the antennas. An antenna system for a base station of a telephone network, comprising at least one antenna according to one of claims 1 to 3. 14. An antenna system for a base station of a telephone network, comprising at least two antennas according to one of claims 1 to 3, for different networks, said at least two antennas being placed at different heights in said system and each antenna being fixed by connecting means bearing at least on the end walls of said antenna, so as to grip it. Antenna system according to claim 13 or 14, including a mast. Antenna system according to claim 14 or 15, comprising at least two groups (80, 81, 82) of three antennas, placed at different heights. 17. Antenna system according to one of claims 14 to 16 comprising at least one profile (9) between two antennas for the same network.