FR2527013A1 - DEPORTABLE ANTENNA FOR PORTABLE OR PORTABLE ELECTROMAGNETIC ELECTROMAGNETIC WAVE TRANSMITTER STATION - Google Patents

Abstract

THE ANTENNA INCLUDES A PART 4 CONDUCTING ELECTRICITY INCLUDING A TAPERED PART 5 ALLOWING TO PLANT THE ANTENNA IN THE GROUND 6 AND A RADIANT ELEMENT 7 FIXED ON THE SUPPORT PART 4 OPPOSITE THE TAPERED PART 5 BY THE INTERMEDIATE OF A CONNECTION BOX 8 ALLOWING THE SUPPLY OF HIGH FREQUENCY ENERGY OF THE DIPOLE FORMED BY THE RADIANT ELEMENT 7 AND THE SUPPORT PART 4. APPLICATION: DEPORTABLE ANTENNA FOR PORTABLE AND PORTABLE TRANSMITTER-RECEIVER STATION OPERATING AT VHF FREQUENCIES OF THE L ' ORDER OF 26 MHZ AND MORE.

Description

DEPORTABLE ANTENNA FOR EMITTER-RECEIVER STATION

  PORTABLE OR PORTABLE ELECTROMAGNETIC WAVES

  The present invention relates to a remote antenna for post

  portable or portable electromagnetic wave transmitter and receiver.

  Antennas for transmitting stations and / or receivers of portable or portable electromagnetic waves are usually fixed on the chassis of the transceiver station, which presents on the plane of

  exploitation, the advantage of having an easily trans-

  On the other hand, in the field of VHF operating frequencies

  of the order of 26 M Hz and above, some of the electromagnetic energy

  The tick radiated by the antenna is absorbed by the carrier of the portable station or of the station attendant who is placed in the vicinity. This loss of energy results in modifications of the antenna radiation pattern.

  and changes in the range of the antenna that carries less.

  To remedy this drawback, one solution is to separate geogra-

  the radiating element of the antenna of the transceiver station and its carrier while connecting the radiating element to the station

coaxial line.

  According to this solution, the radiating element is maintained in a vertical position above the ground by guy wires, and the radiating dipole which consisted of the antenna and the frame of the station is reconstituted using a network of conductors. distributed in a layer on the ground In this solution, the chassis of the station or the network of conductors distributed in sheet, play the role, of what is commonly called in radioelectricity, of

  radioelectric counterweight to the radiating element.

  However, the arrangement obtained is impractical to

  because the installation of the antenna causes many manipulations

  equipment and accessories, bulky and heavy to carry.

  Another solution implemented for radio stations

  mounted on vehicles consists in installing the antenna at the top of a "discone" and "ground plane" mast; but this type of installation which uses heavy and bulky equipment, can not be transposed for

  carry out transmitting and receiving installations which remain easily trans-

  the carrier or the user of the transceiver station, when they are deprived of any vehicle and must move

  geographical regions making progress difficult.

  The object of the invention is to overcome these disadvantages with the aid of an antenna for portable and portable transceiver station, convenient to remotely install the transceiver station, low volume and low weight to make it convenient. transport, while being of sufficient size to be both discreet and robust and allow it to be used on all

more inhospitable.

  To this end, the subject of the invention is a remote antenna for a portable or portable electromagnetic wave transmitter or receiver station, characterized in that it comprises an electrically conductive support part comprising a tapered part enabling the antenna to be pitched in the floor and a radiating element fixed on the support part opposite the tapered part via a connection box, the connection box allowing the high frequency energy supply of the dipole

  radio frequency formed by the radiating element and the support piece.

  The invention will be better understood and other characteristics

  will be made with the following description with reference to the drawings

annexes.

  FIG. 1 represents an example of a transmission installation

  receiving comprising an antenna according to the invention.

  Figure 2 shows an example embodiment of a part

  metal bracket connected to the connection box.

  Figure 3 is an example of a possible representation of a

  adapter circuit placed inside the connection box.

  The installation shown in FIG. 1 comprises a transceiver station 1 connected by a coaxial cable 2 to an antenna 3 according to the invention. The antenna 3 comprises a metallic support piece 4, comprising a tapered portion 5, for planting the antenna in the ground 6 and a radiating element 7 fixed on the support piece 4 opposite the tapered portion 5 by the The connection box 8 makes it possible to supply the radio-frequency dipole formed by the radiating element 7 and the support part 4 with high-frequency electromagnetic energy, thereby ensuring that the radiating element is connected to the radiating element. of the support part 4 with one end of the cable 2, the other end of which is connected to the emission-reception socket 9 of the electromagnetic waves

the transceiver station 1.

  The metal support part 4 is represented in FIG.

  comprises a peg 10 surmounted by a rod or a cylindrical tube 11.

  The stake 10 comprises a conical part 12, forming the tapered portion 5, a connecting piece 13 and an intermediate tube 14 situated between the conical piece 12 and the connecting piece 13 The conical piece 12 comprises, at its base 12a, a cylindrical part 15 which engages inside the end 14a of the tube 14 and a shoulder 16 on which abuts the end 14a of the tube 14 One or more screws 17, or any similar fastening means, ensures the attachment of the end 14a on the part

cylindrical 15.

  The connecting piece 13 comprises two cylindrical portions 18 and 19 separated by a shoulder 20 The generatrices of the cylinders formed by the cylindrical portions 18 and 19 have the same directions The cylindrical portion 18 is engaged inside the end 14b of the tube 14 to bear the end 14b on the shoulder 20 and is fixed in this position on the end 14 bpar at least one clamping screw

  shown or any other similar means of attachment. The cylindrical part

  January 19 has its end face 21 opposite the shoulder 20, slightly curved, to be hammered when necessary when pressing the

  post 10 in the ground, without risk of damaging the fitting part 13.

  The cylindrical tube 11 comprises two ends 11a, 11b and a hole 21a through which the coaxial cable 2 passes, pierced on the cylindrical surface of the tube. The cylindrical tube 11 is removably mounted above and in the extension of the longitudinal axis the post 10 by means of the connecting piece 13, the cylindrical portion 19 freely engages to

  the inside of the end portion 1a of the tube 1.

  To improve the electrical continuity between the stake 10 and the tube 11, an electrical conductor (not shown) may be fixed on the

  respective cylindrical surfaces of the post 10 and the tube 11.

  The connection box 8, also shown in FIG. 2, comprises a support piece 22, matching circuits 23 of the antenna 3 to the coaxial cable 2 and an insulating cylindrical envelope 24, for example made of bakelite, surrounding the adaptation circuits. The support piece 22 comprises a base 25 for fixing the connection box 8 on the end 11b of the tube 11 and a support plate 26 of the matching circuits 23 The base 25 comprises a shoulder 27 between two cylindrical portions 28 and 29 , the generators of cylinders formed having the same direction La

  cylindrical portion 28 engages inside the end llb of the tube II.

  The end I 1b and the cylindrical portion 28 are held together by at least one clamping screw or by any other similar means not shown. The cylindrical portion 29 is provided with a seal 30 and engages with the inside the end 24a of the cylindrical insulating jacket 24 The base 25 also comprises a hole 31, oriented in the

  The direction of the generatrices of the corresponding cylinders of the cylindrical parts

  driques 28 and 29, to allow passage of the end of the coaxial cable 2 and its connection to the matching circuit 23 The base 25 also comprises a flat upper portion 32, located at the end of the cylindrical portion 29, perpendicular in the direction of the generatrices of the cylinder corresponding to the cylindrical part 29, on which the support plate 26 rests. An insulating plate 33, for example made of bakelite, is

  applied on the upper part 32 by a clamping screw 33 bis.

  The upper end 24b of the cylindrical envelope 24 is closed by a sealing tip 34 whose upper portion 35 is threaded for

  receive the threaded end axis 36 of the radiating element 7 of the antenna.

  The lower portion 37 of the tip 34 is cylindrical and is committed to

  the inside of the upper end 24b of the cylindrical envelope iso-

  When the tip 34 is engaged at the end 24b of the connection box 8, the upper end 24b of the cylindrical envelope 24 is in contact on a shoulder 38, of the tip 34, located between the parts

  upper and lower 35 and 37.

  The electrical matching circuits 23 are shown in FIG. 3 They consist of a coil 23a and a capacitor 23b The coil 23 has a first end connected to a connection terminal 39 placed on the lower end of the tip 34 for making the electrical connection between the end of the coil 23a and the end axis 36 of the radiating element 7 The coil 23 has a second end, electrically connected to a terminal 41, placed on the insulating plate 32 and which is connected to the inner wire of the coaxial cable 2 The first end of the coil 23a is also electrically connected to a first end

  capacitor 23b whose other end is connected to the metallic mass

  than the support element 4 via a terminal 40 formed by a ground lug fixed on the upper part of the base 22 by means of the screw 33 bis The outer sheath of the coaxial cable 2 is also electrically connected In this way the electromagnetic energy which is transmitted by the transmitter 1, and transmitted to the radiating element 7 via the coil 23a and across the capacitor 23b The elements 23a and 23b are set to

  adapt the antenna to obtain the desired bandwidth.

  The desired bandwidth can also be obtained by choosing

  The dimensions of the radiating element 7 and of the metal support 4 can be adjusted properly. It is possible, by making the diameters of the radiating element 7 and the metal support 4 to be different, to reduce the overvoltage coefficient of the antenna. by appropriately adjusting the length of the intermediate tube 11, if necessary in

  using several intermediate tubes, vary the feeding point

  of the antenna, which amounts to moving the adaptation housing 8 along the axis of the antenna and thus causes an asymmetrical excitation thereof and an increase in the real part of the impedance of the antenna. antenna which significantly reduces the overvoltage thereof and increases by

therefore its bandwidth.

  The antenna which has just been described makes it possible to obtain

  electromagnetic waves in vertical polarization of which the

  radiation pattern is omnidirectional in natural azimuth

  Other antennas may be obtained by giving the radiating element 7 a shape and a structure different from those just described. In particular, the radiating element may take the form of an elongated, straight or flexible or be constituted by a stretched conductive wire, or be reconstituted by several elements that can fit into each other, in a form for example telescopic:

  Other alternative embodiments of the invention are also possible.

  for example, by making the post 10 in one piece and using, instead of hollow cylindrical tubes, solid bars or rods connected for example by means of sleeves. According to another embodiment, the casing of the connection box may be metallic and its einbase 2, and the support piece 26 may be made of an insulating material, to isolate the two parts of the dipole formed by the radiating element 7 and the support part 4 It will also be noted that the support part 4, instead of being metallic, may be carried out over all or part of its length in an insulating material such as a plastic material sufficiently rigid, to allow the stake 10 to sink into the ground without being damaged In the latter mode of embodiment, an electrical conductor must be placed at the periphery or inside the support part 4, to reconstitute, with the radiating element 7, the dipole

radio frequency of the antenna.

Claims (8)

  1 Remote antenna for radio wave transceiver   portable or portable tromagnetic system, characterized in that it comprises an electrically conductive support part (4) comprising a tapered part (5) for planting the antenna in the ground (6) and a radiating element (7) fixed on the supporting part (4) opposite the tapered part (5) via a connection box (8), the connection box (8) for the high-frequency energy supply of the formed dipole   by the radiating element (7) and the support part (4).   Antenna according to claim 1, characterized in that the supporting part (4) comprises a peg (10) which can be pushed into the overlying ground.   by at least one intermediate rod (II).   Antenna according to claim 2, characterized in that the rod   intermediate (11) is removably placed above the stake (10).   Antenna according to claims 2 and 3, characterized in that   the radiating element is an elongated conductor approximately rectilinear arranged so that the longitudinal axes of the radiating element (7) and   of the peg (10) have about the same direction.   Antenna according to one of Claims 1 to 4,   characterized in that the connection housing (8) has an asymmetrical intermediate position between the ends formed by the tapered portion (5) and the end of the antenna opposite the tapered portion for   broaden the bandwidth of the antenna.   Antenna according to one of Claims 1 to 5,   characterized in that the sections of the radiating element (7) and the support part (4) constituting the electric dipole are made different   to expand the bandwidth of the antenna.   Antenna according to any one of the preceding claims,   characterized in that the length of the support piece (4) is adjustable.   Antenna according to any one of the preceding claims,   characterized in that the connection box (8) contains a circuit   adaptation (23) to act on the bandwidth of the antenna.   Antenna according to any one of the preceding claims,   characterized in that the high frequency energy is supplied to the housing   connection via a coaxial cable (2).   Antenna according to any one of the preceding claims   characterized in that the post (10) comprises a tapered portion (5,12), a connecting piece 13 and an intermediate tube (14) located between the   tapered portion (5) and the fitting piece (13).