FR2621741A1 - ANTENNA TO PASTE ON A GLAZING - Google Patents

Abstract

The invention relates to an antenna for glazing. It relates to an antenna which comprises a dielectric blade 24 turned towards the outside and a dielectric blade 23 turned towards the inside. One of the two internal surfaces of the two dielectric blades 23, 24 carries a conductive antenna pattern 12, while the visible face of the dielectric blade 23 placed inside carries a ground pattern 13. In this way, the The antenna does not protrude outside the glazing and is therefore not subject to bad weather. Application to antennas used for radio telephone communications.

Description

i

  The present invention relates to an antenna comprising

  a conductor forming an antenna pattern on a first face of a dielectric plate to be attached to a glazing, and a ground pattern placed on the other side of the blade. A glazing antenna, supported by a glazing unit or the like constituting a dielectric member of a flat microstrip antenna, has already been developed. Such an antenna is fixed for example to a vehicle so that it

  used as a transmitting-receiving antenna of a tele-

  vehicle phone or receiver antenna of a system

  global positioning system intended to detect the ac-

  the vehicle by receiving radio waves

from a satellite.

  Figures 1 and 2 show a conventional antenna

  glazing unit intended to be attached to a glazing unit above

  of a vehicle. According to this technique, a flat microstrip antenna 14 for glazing is formed by depositing a conductor 12 forming an antenna pattern and

  of a conductor 13 of mass on the outer faces and

dull lla and lib of a glazing 11.

  A transverse hole 15 is formed in the glazing 11.

  An inner conductor 16a of a coaxial cable 16 is

  connected to the conductor 12 forming the antenna pattern by

  the weld 17, through the hole 15. A conductive

  13b of the coaxial cable 16 is connected to the

  mass driver 13 by welding 18.

  In this prior art, however, since the conductor 12 forming the antenna pattern is placed outside and, furthermore, since the solder 17 extends from the conductor 12, the conductor 12 and the like members may be damaged during the brushing operation. course of cleaning the

  vehicle or oxidized by rain, inclement weather and

gists.

  In addition, when droplets of water or

  logues adhere to the driver 12 forming the drawing of

  tenne or the like, the impedance of the conductor 12 or the like

  is modified. Accordingly, according to the prior art

  the preservation of emission characteristics-

  High quality reception is difficult.

  Since the conductor 12 forming the antenna pattern is disposed at the surface 11a of the glazing 11, and furthermore the solder 17 extends from the conductor 12, the external appearance

  of the aforementioned conventional antenna is not perfect.

  The present invention relates to a glazing antenna comprising a dielectric member intended to be

  fixed to a glazing so that first surfaces practically

  two dielectric blades, having practically

  the same extent, are placed facing each other, a second surface of the dielectric blades being turned towards an inner side while a second surface of the other of the dielectric blades is facing an outer side, a antenna pattern conductor placed between the two surfaces, and a ground conductor placed at the second

  surface turned to the inner side.

  In the glazing antenna according to the invention, the conductor forming the antenna pattern is placed between the first surfaces of the two dielectric plates, and the ground conductor is placed on the surface of one of the two dielectric blades facing the inside. As a result, neither the conductor forming the antenna pattern nor the ground conductor is placed outside and they therefore stand up well to physical and

chemicals and the like.

  Moreover, in the dielectric member, the first surfaces of the two dielectric plates in their entirety, practically having the same extent, are

  arranged opposite. Consequently, no defect of regulation

  larity does not appear on the surface of the dielectric

turned to the outside.

  In the glazing antenna according to the invention, such as the conductor of the antenna pattern and the ground conductor

  are resistant to physical and chemical changes and

  logues, high transmission-reception characteristics

quality can be preserved.

  Moreover, since no regularity defect exists at the outer surface of the dielectric member, the appearance

obtained can be excellent.

  Other features and advantages of the invention

  will be better understood by reading the description

  which will follow, made with reference to the accompanying drawings in which:

  FIG. 1 is a section of an antenna of the

  former line along line I-I of Figure 2; Fig. 2 is a plan view of the antenna of the prior art; and Figures 3 to 9 are partial sections of seven

  embodiments of the present invention.

  The seven embodiments of the invention,

  a flat microstrip antenna for a top glazing of a vehicle, are now described in

reference to Figures 3 to 9.

  Figure 3 represents the first mode of

  tion. In this one, a laminated glass is used as glazing 21. This glazing 21 is made so that the first surfaces 23a and 24a of two glass plates 23 and 24, practically in their entirety and having practically the same

  extended, are placed opposite an intermediate layer

  diaire 22 formed of a transparent adhesive.

  The glazing 21 is fixed in a window so that a second surface 23b of the blade 23 is turned inward while a second surface 24b of the blade 24

is turned to the outside.

  A conductor 12 forming an antenna pattern is

  deposited on the surface 23a of the blade 23 while a conductor

  13 is deposited on the surface 23b of the blade 23.

  It should be noted that a coaxial cable (not shown) is attached

  to the glazing in a manner known from the prior art

  as shown in Figures 1 and 2.

  Figure 4 represents the second embodiment of

  tion. This is practically the same arrangement as the first embodiment, but the conductor 12 forming the antenna pattern is deposited on the surface 24a of the blade

of glass 24.

  Figure 5 represents a third embodiment of

  tion. This is substantially the same arrangement as the first embodiment, but a resin blade is formed of a transparent plastic or the like and is used in place of the glass slide 24 and the

intermediate layer 22.

  Since the third embodiment having this arrangement requires a smaller number of members than the first and second embodiments, its manufacture

is facilitated.

  Figure 6 represents a fourth embodiment of

  tion. This is practically the same arrangement as the first embodiment, but a transverse hole 26

  formed in the glass slide 24 and the intermediate layer

  22 in the parts corresponding to the conductor 12 forming the antenna pattern, and a sealing member 27, constituted by a member having a permittivity lower than

  that of glass, is introduced by the hole 26.

  When an organ formed of a material having a

  high mitigation, such as glass, is placed near an antenna element, the decoupling ratio of the antenna element increases and the gain of this element is reduced compared with the case where the antenna element is in contact with the air. The following table shows the gains obtained in

  direction perpendicular to the conductor 12 of the drawing of

  when the members formed of different materials are placed close to the outer face of the conductors 12 in the state shown in FIG. 6. It should be noted that the values given in the table have been obtained in FIG.

  the assumption that the gain was equal to zero decibel

  that no member was placed on the outer face of each conductor 12 forming the antenna pattern, i.e.

air was in contact with him.

  NO. Frequency 1.5 GHz 0.9 GHz Element 1 Glass only (thickness = 2.1 mm) -0.6 dB -0.5 dB 2 Glass + intermediate layer (thickness of the layer

intermediate = 0.7 mm) -1.2 dB -

3 glass + two layers

Intermediate -1.5 db -

  4 - "Teflon" only -0.1 dB 0 dB As indicated in this table, when the sealing member 27 formed of "Teflon" is used, the reduction of

  gain is very small. In place of "Teflon" (permitti

  v = 2), one can use a silicone (= 2.75), a poly-

  carbonate (= 3), polyethylene (= 2.3) or a similar material as material of the sealing member 27. All these materials have permittivities lower than that

  of a vehicle glazing (permittivity = 7 to 8).

  Figure 7 represents the fifth mode of

  tion. It has practically the same arrangement as the fourth embodiment, but the hole 26 is formed in the glass plate 23 and the intermediate layer 22 has corresponding locations to the ground conductor 23,

  and the sealing member 27 is introduced through the hole 26.

  In the fifth embodiment having this arrangement, the gain obtained may be greater than that which

  is obtained with the first and second modes of

tion.

  Figure 8 represents the sixth embodiment of

  tion. This one has practically the same layout as the fourth and the fifth embodiment, but the hole

  26 is formed in the blades 23 and 24 and the intermediate layer

  22 in portions corresponding to the ground conductor 13, the two sealing members 27 penetrating into

  the hole 26 so that they keep the driver 12 for-

the antenna pattern between them.

  In the sixth embodiment having this arrangement, the gain obtained may be greater than that of the fourth and fifth embodiments.

  Figure 9 represents the seventh mode of

  tion. This is practically the same arrangement as the fourth embodiment, but a blade-like member 28 formed of the same material as the sealing member.

  27, is used in place of the glass slide 24.

  In the seventh embodiment having this

  disposal, the steps of forming hole 26 and introducing

  duction of the sealing member 27 may be omitted

  in the manufacturing operation and consequently the manufacturer

cation is facilitated.

  In the embodiments described above, the invention is applied to a flat microstrip antenna for glazing intended to be fixed to an upper opening of a vehicle. However, the invention is suitable for an antenna intended to be fixed to the rear window of a vehicle. In addition, the invention can be applied to antennas intended to be attached to means of transport

  other than a motor vehicle, to buildings and

  gists. Of course, various modifications may be made by those skilled in the art to antennas that come

  to be described only as non-limita-

  without departing from the scope of the invention.

Claims (6)

  Antenna for glazing, characterized in that it comprises: a dielectric member (21) to be fixed to a glazing so that first surfaces (23a, 24a) of two dielectric blades (23-25, 28), substantially in their entirety and having substantially identical expanses, are arranged facing each other, and that a second surface (23b) of one of the dielectric blades (23-25, 28) faces inwards while a second surface (24b) on the other dielectric blades (23-25, 28) is facing outwards, a conductor (12) forming an antenna pattern placed between the first surfaces (23a, 24a), and a conductor mass (13) placed on the second   surface (23b) facing inwards.   Antenna according to claim 1, characterized in that   a part of at least one of the two dielectric blades   and at least one of the conductors (23, 25, 28) corresponding to at least the conductor (12) forming the antenna pattern is formed of a material having a lower permittivity than the other parts. Antenna according to claim 2, characterized in that a part of the dielectric plate (24) on the outer side, corresponding to the conductor (12) forming the antenna pattern, is made of a material having a   permittivity lower than those of the other parts.   Antenna according to claim 2, characterized in that a portion of the dielectric plate (23) on the inner side, corresponding to the ground conductor (13), is formed of a material having a lower permittivity to that of the other parties.   5. Antenna according to claim 2, characterized in that the parts of the two dielectric plates (23, 24) which correspond to the ground conductor (13) are formed of a material having a permittivity lower than those other parties.   Antenna according to claim 2, characterized in that the dielectric plate (28) on the outer side is formed of a material having a permittivity less than   that of the dielectric plate (23) placed on the inner side.