FR2478378A1 - GEOSTATIONARY SATELLITE TELECOMMUNICATION ANTENNA SUPPORT AND ANTENNA COMPRISING SUCH A SUPPORT - Google Patents

Abstract

THE PRESENT INVENTION CONCERNS A SUPPORT FOR POINTING A TELECOMMUNICATION ANTENNA TOWARDS A GEOSTATIONARY SATELLITE. IT INCLUDES A TUBE 1 THAT CAN PIVOT ON ITS AXIS OF SYMMETRY AND INCLUDING A FIRST ARM 5 ON WHICH THE ANTENNA 10 IS HINGED AND A FLANGE 3 THAT CAN SLIDE ON THE TUBE 1 AND BEING SOLID WITH THE ANTENNA 10 THROUGH THE INTERMEDIATE D 'A SECOND ARTICULATED ARM 7, THUS ALLOWING BY SLIDING OF THE FLANGE 3 THE SITE ADJUSTMENT OF THE ANTENNA, AND BY ROTATION OF THE TUBE1 THE AZIMUT ADJUSTMENT OF THIS SAME ANTENNA. THIS ANTENNA SUPPORT SEES ITS APPLICATIONS, ESPECIALLY FOR THE DIRECT RECEPTION OF TELEVISION TRANSMISSION BY SATELLITE.

Description

The present invention relates to a support

  geostatic satellite telecommunication antenna

  and more particularly of a parabolic antenna

  small size, for direct reception of television broadcasts from a geostationary satellite. The invention also relates to a

antenna comprising such a support.

  In the case of the reception of

  vision, the sharp increase in the power of

  the satellites has made it possible to reduce

  antennas, of a generally parabolic shape, and has made it possible to envisage the direct reception of satellite television broadcasts, each television receiver being then able to be associated with an antenna, for example a satellite dish,

  of small size pointed at the geostation-

issuer.

  Since the satellite is geostationary, the antenna

  can be pointed once and for all in the direc-

  transmission satellite. However, it is necessary to be able to adjust the antenna, azimuth and site setting, at the time of installation, to

simple and precise way.

  On the other hand, it may also be necessary to be able to change these settings so as to point

  the antenna on another satellite, of different

  rent compared to the one on which the antenna was

  initially set. However, this case remains relatively

  exceptionally, because, in view of the language problems, users of television receivers will only have to receive the most

  often only emissions from a single satellite.

  The antenna supports of small size, according to the prior art, are miniaturization of the supports of the large antennas of the reception centers, these supports being provided with expensive and relatively complicated adjustment elements. In addition, in the case of small antennas for receiving television programs, these elements of complicated settings, are virtually useless,

  since they are only used during the installation

  of the antenna, and in the very rare case where

  wants to change satellite transmitter.

  The present invention provides an antenna support

  not simple and economical, allowing the user an easy adjustment of the azimuth and the site of this antenna

during installation.

  In fact, the telecommunication antenna support

  geostationary satellite transmission according to the invention, for fixing the antenna on a base, while allowing its adjustment, comprises: a tube fixed to the base by fixing means for rotating the tube on its axis of symmetry, and comprising a first arm on which an upper lug integral with the antenna is articulated, - a flange fixed around the tube so as to slide on the latter and comprising means for locking it on this tube, - a second arm one end is articulated on the flange, while the other is articulated to at least one ear integral with the antenna in a different area from that of the upper ear, so that when the flange slides on the tube , the antenna is subjected to a rotational movement in a plane allowing its adjustment in site, and so that when the tube rotates on its axis of symmetry, the antenna is subjected to a rotational movement in a plane perpendicular to the previous edent and allows

both its azimuth setting.

  Other features and advantages of the invention

  will be apparent from the following description given

  non-limiting example and illustrated by the appended figures which represent:

  FIGS. 1a, 1b and 1c, a first embodiment of

  according to the invention, provided with a parabolic antenna, FIG. 2, a second embodiment of a support according to the invention, FIG. 3a, Db, a third embodiment.

a support according to the invention.

  A paraboloidal antenna 10 is symbolized figure la. This antenna is mounted on its support and has the axis of the dish pointed towards the transmitting satellite. The support comprises a tube 1 whose ends

  are clamped by collars 2. These collars comprise

  two arcuate portions, both of which are held around the tube 1 by

tightening bolts.

  One of the two parts of the collars 2 is

  4, through which the collars 2, and thus the tube 1, can be fixed on a base 11, this base 11 being able to be for example a

  vertical wall as shown in Figure la.

  When the clamping bolts of the collars 2 are loosely tightened, the tube 1 held by these collars 2 can rotate inside thereof, on its axis of symmetry. When the bolts are blocked, the tube 1 is held securely. The tube 1 is provided at one of its ends with an arm 5 at the end of which articulates an upper lug 6 secured to the antenna 10 and fixed on its

outer surface.

  This arm 5 is shown in more detail in FIG. TI comprises two metal strips 5a welded to the tube 1 and preformed so as to constitute with the tube 1 an isosceles triangle whose base is the diameter of the tube 1 and the top. the upper ear 6 on which is fixed the end of

arm 5.

  Indeed, the two blades 5a pinch the upper ear 6, and can be maintained by

  a bolt so that the antenna 10, through the

  intermediate of his upper ear 6, is articulated

relative to the arm 5.

  On the other hand, a flange 3 is positioned around the tube 1. This flange comprises two half-flanges, obtained for example from plate plates stamped so as to take each the shape of a half-cylinder. The two half-flanges are held around the

  tube 1 with screws or bolts 9.

  the flange 3 can slide along the tube 1.

  This flange 3 is integral with an arm 7 shown more

in detail in figure ic.

  Indeed Figure lc, the two half-flanges 3a have been shown in cross section, positioned around the tube with two bolts 9. The arm 7 comprises two identical metal blades 7a. These two blades have one of their ends pressed against each other between the two demibrides by one of the

tightening bolts 9.

  These two blades 7a are preformed so as to form an isosceles triangle whose apex is the clamping bolt 9 which clamps the two ends of these two blades 7a, and the base, the distance between two

  ears 8a positioned on the antenna 10.

  Indeed, the two lugs 8a are secured to the antenna 10, at a predetermined distance from the upper lug 6, so as to form, in a preferential case, an isosceles triangle whose apex is the upper lug 6 and the base, the distance

between the two ears 8a.

  The ends of the metal blades are now

  held on the ears 8a by clamping bolts.

  The clamping bolts are equipped with devices such as washers, so as to allow a good articulation of the arm 7 with respect, on the one hand, to the flange 3 and, on the other hand, to the lugs 8a of

the antenna 10.

  In the case of FIG. 1a, when the flange 3 is slid upwards, the arm 7 transmits a force to the antenna 10 sufficient to rotate it on its point of support represented by the upper lug 6 , the axis of the paraboloid then approaching the vertical position. On the other hand, when the flange 3 slides downwards, the arm 7 transmits a force of the opposite direction of the preceding one, to the antenna causing its pivoting, the axis of the paraboloid

  approaching in this case the horizontal position.

  the flange 3 thus makes it possible to orient the direction of the axis of symmetry of the paraboloid of the antenna 10, in a vertical plane, thus making it possible to adjust the

antenna site 10.

  On the other hand, the tube 1 can pivot on its axis of symmetry using the collars 2, and the antenna 10 being secured to the tube 1 via the arms 5 and 7, the antenna 10 can rotate. in a horizontal plane, in the case of Figure la, this plane being perpendicular to the plane of displacement in the

case of site tuning.

  the pivoting of the tube 1 thus makes it possible to orient the direction of the axis of symmetry of the paraboloid of the antenna 10 in a horizontal plane perpendicular to the preceding one, thus making it possible to adjust the azimuth of

the antenna 10.

  when installing antenna 10, the installation

  Thus, the starter fixed at first the support of the antenna 10, via the feet 4 of the collars 2, on a base 11. the case of the figure allows it to be fixed on a vertical base, such as for example a Wall. the support can be fixed on the wall

  so that the tube 1 is in a meridian plane.

  The installer can then act on the flange 3 so that the axis of the paraboloid of the antenna 10 is made with the vertical of the place where the antenna is mounted, an angle equal to the latitude of the location of the antenna.

- the antenna.

  the position of the axis of the paraboloid being related to the position of the flange 3, it is possible to locate the position of this axis by graduating the tube 1 by marks 15, each reference corresponding to a position

  precise flange 3 and therefore the axis of the paraboloid.

  After an initial calibration, a concordance table

  - dance gives the mark 15 corresponding to the latitude - of the place oh must be placed the antenna 10, latitude which it is known. So the axis of the paraboloid is in

  a plane substantially parallel to the plane of the equator.

  the geostationary satellites being in the plane of the equator and at a latitude substantially equal to 36,000 Km, it is possible to select the satellite to receive by rotating the antenna 10 in a horizontal plane, that is to say by intermediary

collars 2 on the tube 1. -

  To do this, the collars 2 can be graduated so that a mark of this graduation

  corresponds to a transmitting geostationary satellite.

  This setting can be refined by connecting the antenna 10 to a control receiver and slightly modifying the initial settings to obtain

the best image possible.

  The settings completed, the antenna can be blocked by tightening all the bolts of the collars 2

and the flange 3.

  FIG. 2 represents a second embodiment of

  the support according to the invention.

  In this case, the support of Figure la is fixed via the feet 4 of the collars 2 on a base comprising a pole which, in a preferred mode is of square section, and a horizontal slab 30 in which is planted the pole 16, this slab can be, for example, a concrete slab. This embodiment allows for example the

  fixing the antenna in a garden.

  Figure 3a shows a third embodiment of the invention. Here the tube 1 equipped with its

  arm 5 and its flange 3 no longer has a fixing collar

  tion, but have lower end plugged into

a base including a foot 20.

  This foot 20 has a hollow cylindrical portion 22 in which is positioned the tube 1, this cylindrical portion is held in a vertical position on

  a horizontal plate 23 by 4 support pieces 21.

  This foot is shown in plan view in Figure 3b.

  The edge of the cylindrical portion 22 is graduated by marks 17 equivalent to those arranged on the collars 2 of Figures 1a and 2, the tube 1 being pivotable on its axis of symmetry within this cylindrical portion so as to adjust the antenna azimuth 10. Locking means of the tube 1 such as a stop screw can be associated

to this cylindrical portion 22.

  The plate 23 is fixed on a horizontal slab 30. These antenna supports thus allow easy adjustment of the antenna 10 and are more particularly adapted, although not exclusively, to the introduction of antennas intended to be oriented definitively

to the same satellite.

  These types of antenna support are more particularly

  suitably adapted to direct reception antennas

  broadcast satellite television.

Claims (10)

  1. Geostationary satellite telecommunication antenna support for attaching the antenna (10) to a base (11) while allowing its adjustment, characterized in thatcomporte - a tube (1) fixed to the base (11) by fastening means allowing a rotation of the tube (1) on its axis of symmetry, and comprising a first arm (5) on which articulates an upper lug (6) integral with the antenna (10), - A flange (3) fixed around the tube (1) so as to slide thereon and having means (9) for locking it on the tube (1), - a second arm (7) whose end is articulated on the flange (3) while the other end is articulated to at least one lower lug (8) integral with the antenna (10) in a different area from that of the upper lug (6), so that when the flange (5) slides on the tube (1), the antenna (10) is subjected to a rotational movement in a plane allowing its adjustment in site, and e way that when the tube (1) rotates on its axis of symmetry,   the antenna (10) is rotated   in a plane perpendicular to the preceding and allowing its adjustment in azimuth.   2. Support according to claim 1, characterized in that the tube (1) is fixed on a base (11) vertical by means of at least two collars (2) having two half-collars clamped on the tube   by means of clamping while allowing rotation   tion of the tube on its axis of symmetry, said collars being provided with a foot (4) for fixing on the vertical base. 3. Support according to claim 2, characterized in that the base (11) comprises a vertical pole   (16) plugged into a horizontal slab (30).   4. Support according to claim 2 or 3,   characterized in that the two collars (2) have a graduation for locating the position of the   tube (1) when it pivots on its axis of symmetry.   5. Support according to claim 1, characterized in that the base (11) of the tube (1) comprises a foot (20) comprising a hollow cylindrical portion (22)   kept upright on a horizontal plate   zontal (23), and in which one end of the tube (1) is plugged in, the tube (1) being able to pivot on its   axis of symmetry inside this cylindrical part drique (22).   6. Support according to claim 5, characterized in that the hollow cylindrical portion (22) comprises a graduation for locating the position of the   tube (1) when it pivots on its axis of symmetry.   7. Support according to one of claims 1 to 6,   characterized in that the flange (3) comprises two half   flanges (3a) in an arc, held around the   tube (1) by at least two clamping bolts (9).   8. Support according to claim 7, characterized in that the second arm (7) comprises two blades (7a) preformed to form an isosceles triangle whose apex is one of the clamping bolts (9) of the flange (3). and the base, the distance between two ears   internal (8a) integral with the antenna (10).   9. Support according to one of claims 1 to 8,   characterized in that the tube (1) comprises a   duation to identify the position of the flange (3) on this one.   1 1 10. Antenna reception, characterized in that it comprises a support according to one of Claims 1 to 9.