CN112909491A

CN112909491A - Be applied to on-vehicle glass antenna

Info

Publication number: CN112909491A
Application number: CN202110082596.4A
Authority: CN
Inventors: 班涛; 董梦银; 潘成伟
Original assignee: Fuyao Glass Industry Group Co Ltd
Current assignee: Fuyao Glass Industry Group Co Ltd
Priority date: 2021-01-21
Filing date: 2021-01-21
Publication date: 2021-06-04
Anticipated expiration: 2041-01-21
Also published as: CN112909491B

Abstract

The invention discloses a vehicle-mounted glass antenna, which comprises glass, a balun structure arranged in the glass, and an antenna unit arranged on the inner surface of the glass, wherein the antenna unit comprises a radiator and a ground plate, the inner surface of the glass is also connected with one side of a dielectric plate, the other side of the dielectric plate is also provided with a microstrip feeder line, the microstrip feeder line is respectively coupled with the radiator and the balun structure, and the microstrip feeder line is used for being electrically connected with a control device. According to the invention, the antenna unit and the balun structure are respectively arranged on the glass, so that the omnidirectional and low cost of the V2X antenna can be realized while the low profile is realized. The dielectric plate is arranged on the inner surface of the glass, so that the overall height of the antenna is reduced, the antenna is easy to process, and the production cost is low.

Description

Be applied to on-vehicle glass antenna

Technical Field

The invention relates to the field of intelligent traffic equipment, in particular to a vehicle-mounted glass antenna.

Background

The Vehicle networking (V2X, Vehicle-to-evolution) is used for realizing all-around connection and communication between a Vehicle and surrounding vehicles, people, traffic infrastructure, networks and the like, and has outstanding advantages in the aspects of improving traffic efficiency, improving driving safety, reducing accident rate, saving energy, reducing emission and the like. At present, the on-vehicle V2X antenna mountable is in external shark fin, and external shark fin can influence the appearance design of automobile body, increases the windage of increase car when increasing the design degree of difficulty, nevertheless places the V2X antenna in the automobile body, for satisfying the omnidirectional radiation in the 15 pitching angle scope about the V2X antenna, the position of laying of V2X antenna is more restricted, if adopt the distribution all around then increase product cost.

Disclosure of Invention

In order to solve the problems, the invention provides a vehicle-mounted glass antenna; the antenna unit and the balun structure are respectively arranged on the glass, so that the omnidirectional and low-cost V2X antenna can be realized while the low profile is realized.

In order to achieve the purpose, the technical scheme adopted by the invention comprises the following steps: the utility model provides a be applied to on-vehicle glass antenna, includes glass, still includes the balun structure that sets up inside glass and sets up the antenna element on the glass internal surface, antenna element includes irradiator and ground plate, the internal surface of glass still is connected with one side of dielectric plate, the opposite side of dielectric plate still is provided with the microstrip feeder, the microstrip feeder is connected with irradiator and balun structure coupling respectively, the microstrip feeder is used for with the controlling means electric connection.

As a preferred technical scheme of the invention: the radiator and the grounding plate are formed in an integrated manufacturing mode.

As a preferred technical scheme of the invention: the radiator is of an annular structure and comprises a plurality of dipoles which are periodically distributed and/or uniformly distributed.

As a preferred technical scheme of the invention: the tail ends of the dipoles are connected with one end of an impedance converter through a power divider, the other end of the impedance converter is connected with a ground plate, an adjusting gap is formed in the ground plate, and the microstrip feeder line is in coupling connection with the radiator gap through the adjusting gap.

As a preferred technical scheme of the invention: the number of the dipoles is three, and the interval between every two adjacent dipoles is 120 degrees.

As a preferred technical scheme of the invention: the power divider is in a regular hexagon shape.

As a preferred technical scheme of the invention: the number of the dipoles is four, and the interval between every two adjacent dipoles is 90 degrees.

As a preferred technical scheme of the invention: the power divider is in a diamond shape.

As a preferred technical scheme of the invention: the balun structure comprises a plurality of balun elements, the number of balun elements corresponding to the number of dipoles.

As a preferred technical scheme of the invention: the tail ends of the plurality of balun units are connected with the output end of the phase controller, the input end of the phase controller is connected with one end of the impedance converter, the other end of the impedance converter is connected with a first microstrip feeder line, and the first microstrip feeder line is in coupling connection with the radiator gap through the adjusting gap.

As a preferred technical scheme of the invention: the balun unit is in the shape of

And the projection of the balun unit on the antenna unit is projected on the corresponding radiator.

As a preferred technical scheme of the invention: the dipoles are meander dipoles.

As a preferred technical scheme of the invention: the glass is laminated glass and comprises inner-layer glass, a middle layer and outer-layer glass; the balun structure is arranged between the inner layer glass and the outer layer glass, and the antenna unit is printed on the outer surface of the inner layer glass.

Compared with the prior art, the invention has at least the following beneficial effects:

(1) the antenna unit and the balun structure are respectively arranged on the glass, so that the omnidirectional and low-cost V2X antenna can be realized while the low profile is realized. The dielectric plate is arranged on the inner surface of the glass, so that the overall height of the antenna is reduced, the antenna is easy to process, and the production cost is low.

(2) The antenna unit and the balun structure are arranged on the glass in a printing mode, horizontal omnidirectional radiation can be achieved, meanwhile, the whole antenna module is basically hidden on the glass, only the dielectric plate with the microstrip feeder line needs to be installed subsequently, and operation is simple.

(3) The antenna unit and the balun structure are coupled with the microstrip feeder line by adopting a gap, so that glass is not damaged, and water leakage in the using process can be prevented or the strength of the glass is reduced.

Drawings

FIG. 1 is a cross-sectional view of the overall construction of the present invention;

FIG. 2 is a schematic diagram of the overall structure when the number of printed dipoles is four;

FIG. 3 is a schematic diagram of the overall structure when the number of printed dipoles is three;

fig. 4 is a schematic diagram of the overall structure of the antenna unit when the number of printed dipoles is four;

fig. 5 is a schematic diagram of the overall structure of the antenna unit when the number of printed dipoles is three;

FIG. 6 is a schematic diagram of the overall structure of the balun structure when the number of printed dipoles is four;

FIG. 7 is a schematic diagram of the overall structure of the balun structure when the number of printed dipoles is three;

FIG. 8 is a schematic diagram of the overall structure of a microstrip feed line;

FIG. 9 is a return loss S11 plot for a V2X antenna of the present invention;

fig. 10 is a horizontal plane directional diagram of the V2X antenna of the present invention.

In fig. 1-10, 1, glass, 2, balun structure, 3, antenna unit, 4, radiator, 5, ground plane, 6, dielectric plate, 7, microstrip feed line, 8, dipole, 9, power divider, 10, impedance transformer, 11, left arm, 12, right arm, 13, slot, 14, transmission line, 16, adjustment slot, 17, first radiation patch, 18, second radiation patch, 19, balun unit, 20, phase controller, 21, first impedance transformer, 22, first microstrip feed line, 23, long side, 24, short side, 25, connecting side, 26, third radiation patch, 27, fourth radiation patch, 28, inner glass, 29, intermediate layer, 30, outer glass.

Detailed Description

In order that the objects and advantages of the invention will be more clearly understood, the invention is further described in detail below with reference to examples. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It should be noted that in the description of the present invention, it is to be understood that the terms "left", "right", "inner", "outer", etc. indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, which are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," "fourth," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicit to a number of indicated technical features.

As shown in fig. 1-3, an embodiment of the present invention provides a vehicle-mounted V2X glass antenna, which includes a glass 1, a balun structure 2 disposed inside the glass 1, and an antenna unit 3 disposed on an inner surface of the glass 1, where the antenna unit 3 includes a radiator 4 and a ground plate 5, the inner surface of the glass 1 is further connected to one side of a dielectric plate 6, the other side of the dielectric plate 6 is further provided with a microstrip feeder 7, the microstrip feeder 7 is respectively coupled to the radiator 4 and the balun structure 2, the microstrip feeder 7 is configured to be electrically connected to a control device (not shown in the figure), and the control device may select a device in the prior art for processing electromagnetic waves, which is used for processing electromagnetic waves received by an antenna or transmitting electromagnetic waves through the antenna. In the embodiment, the balun structure 2 and the antenna unit 3 are arranged on the glass 1, the balun structure 2 realizes balance-unbalance conversion and omni-directionality within a range of up and down 15 degrees of elevation and depression angles of the antenna unit 3, the dielectric plate 6 can be directly adhered to the inner surface of the glass 1, the overall height of the antenna is reduced, the antenna is easy to process, and the production cost is low; the balun structure 2 is printed on the inner side of the glass 1, so that horizontal omnidirectional radiation can be realized, meanwhile, the whole antenna module is basically hidden on the skylight glass 1, only the dielectric plate 6 with the feed is required to be installed subsequently, the operation is simple, and the industrial applicability is better. It should be understood that the balun structure 2 and the antenna unit 3 may be disposed on the glass 1 in a printing form or in a patch form, but not limited thereto. Optionally, the antenna unit 3 is used as a conductor layer, and the radiator and the ground plate thereof may be formed in the same conductor layer in a coplanar manner, and have both radiation and grounding functions, so that separate fabrication and overlapping of the radiation unit and the grounding unit are avoided, and the overall lamination thickness can be reduced, thereby achieving a low profile height of the antenna, and in addition, the antenna is convenient for saving process cost and mass production.

As shown in fig. 4 and 5, the radiator 4 is a ring structure and includes a plurality of printed dipoles 8 distributed periodically and/or uniformly, ends of the plurality of printed dipoles 8 are connected to one end of an impedance transformer 10 through a power divider 9, the other end of the impedance transformer 10 is connected to the ground plane 5, the printed dipoles 8 include a dipole double arm and two transmission lines 14, the dipole double arm includes a left arm 11 and a right arm 12, the left arm 11 and the right arm 12 are respectively connected to ends of the transmission lines 14, ends of the transmission lines 14 are connected to the power divider 9, the left arm 11 and the right arm 12 are mirror-symmetric, a gap 13 is further disposed between the two transmission lines 14, the dipole double arm serves as a main radiator of the antenna, and the transmission lines 14 are used to improve impedance characteristics of the antenna and are connected to the impedance transformer 10 at the rear end. It is understood that the dipole may be printed or patch type, but not limited thereto. An adjusting gap 16 is arranged on the grounding plate 5, the microstrip feeder 7 is in gap coupling connection with the radiator 4 through the adjusting gap 16, namely the microstrip feeder 7 transmits electromagnetic waves to the radiator 4 through the adjusting gap 16, so that the gap coupling connection is realized, and meanwhile, the microstrip feeder 7 transmits the electromagnetic waves to the radiation balun structure 2 through the adjusting gap 16, so that the gap coupling connection with the balun structure 2 is realized; the microstrip feeder 7 is in slot coupling connection with the balun structure 2 and the antenna unit 3, and compared with microstrip line feeding, coaxial feeding and other modes, the structure of the glass 1 is not changed, and the problems of water leakage or strength reduction and the like of the glass 1 caused by the change of the structure are prevented. The adjusting slot 16 may be in a dumbbell shape, an i-shape, an H-shape, or an L-shape, and is preferably in a dumbbell shape, that is, the first radiation patch 17 and the second radiation patch 18 are respectively disposed at two ends of the adjusting slot 16, the first radiation patch 17 and the second radiation patch 18 are in a circular shape, the working frequency band of the antenna can be changed by changing the radius of the first radiation patch 17 and the radius of the second radiation patch 18, and the input impedance can be adjusted by changing the width of the adjusting slot 16.

Further, the printed dipole 8 is preferably a meander dipole, i.e. the left arm 11 and the right arm 12 are each angled with respect to the transmission line 14. The number of the printed dipoles 8 can be three, and the interval between every two adjacent printed dipoles 8 is 120 degrees; the power divider 9 may have a regular hexagonal shape, a circular shape, an elliptical shape, or the like. Or the number of the printed dipoles 8 is four, and the interval between two adjacent printed dipoles 8 is 90 degrees; the power divider 9 may have a rhombic shape, a circular shape, an elliptical shape, or the like.

As shown in fig. 6 and 7, the balun structure 2 is also a ring structure, that is, the balun structure 2 may include a plurality of periodically and/or uniformly distributed balun units 19, the balun units 19 are disposed on the glass in a printing manner, the number of the plurality of balun units 19 corresponds to the number of the plurality of printed dipoles 8, for example, when the number of the printed dipoles 8 in the radiator 4 is three, the number of the corresponding balun units 19 is also three, and the projections of the plurality of balun units on the antenna unit are projected on the corresponding printed dipoles 8; the tail ends of the balun units 19 are connected with the output end of the phase controller 20, the input end of the phase controller 20 is connected with one end of the first impedance converter 21, the other end of the first impedance converter 21 is connected with a first microstrip feed line 22, and the first microstrip feed line 22 is coupled with the slot 13 of the radiator 4 through the adjusting slot 16. The electromagnetic wave is coupled with the first microstrip feeder 22 slot 13 through the adjusting slot 16, so that the structural characteristics of the glass 1 are not damaged while coupling feeding is realized; the balun element 19 has a shape of

The shape is that the balun unit 19 comprises a long side 23, a short side 24 and a connecting plate 25, the long side 23 and the short side 24 are connected through the connecting plate 25, and one end of the long side 23 is connected with the phase controller 20; the projection of the balun unit 19 on the printed dipole 8 is that the long side 23 projects onto the left arm 11, the short side 24 projects onto the right arm 12, the connecting plate 25 is perpendicular to the slot 13, and the projection of the first microstrip feed line 22 on the ground plate 5 is perpendicular to the adjusting slot 16; the phase controller 20 is a phase controller 20 that can be changed, and different phase feeding can be realized by changing the length of the phase controller 20, and the phase controller can also be used to realize a directional antenna. And the balun unit 19 realizes the homodromous of currents of two arms of the dipole antenna and ensures the normal work of the dipole antenna.

As shown in fig. 8, one end of the microstrip feed line 7 is provided with a third radiation patch 26, one end of the first microstrip feed line 22 is provided with a fourth radiation patch 27, the third radiation patch 26 and the fourth radiation patch 27 are circular in shape, and the impedances of the microstrip feed line 7 and the first microstrip feed line 22 can be adjusted by adjusting the radii of the third radiation patch 26 and the fourth radiation patch 27.

Further, the glass 1 may be a laminated glass 1 including an inner layer glass 28, an intermediate layer 29 and an outer layer glass 30; the balun structure 2 can be arranged between the inner layer glass and the outer layer glass, preferably printed on the inner surface of the inner layer glass 28, the antenna unit 3 is printed on the outer surface of the inner layer glass 28, and the inner layer glass 28 is used as a dielectric plate of the balun structure 2 and the antenna unit 3, so that the omni-directional property and low cost of the V2X antenna can be realized while the low profile is realized, the installation is convenient, and the performance is stable. As shown in fig. 9 and 10, taking the V2X antenna with four printed dipoles as an example, the impedance bandwidth range of the return loss S11 corresponding to-10 dB or less is 5.32 GHz-7 GHz, and the operating frequency band including V2X can be used to implement the car networking function. Meanwhile, the out-of-roundness of the antenna in the horizontal plane is less than 2dB, and the omni-directional index of the V2X antenna is basically met.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that those skilled in the art can make various improvements and modifications without departing from the principle of the present invention, and these improvements and modifications should also be construed as the protection scope of the present invention.

Claims

1. The utility model provides a be applied to on-vehicle glass antenna, includes glass, its characterized in that: the antenna unit comprises a radiating body and a ground plate, the inner surface of the glass is further connected with one side of a dielectric plate, a microstrip feeder line is further arranged on the other side of the dielectric plate, the microstrip feeder line is respectively in coupling connection with the radiating body and the balun structure, and the microstrip feeder line is used for being electrically connected with a control device.

2. The glass antenna applied to the vehicle as claimed in claim 1, wherein: the radiator and the grounding plate are formed in an integrated manufacturing mode.

3. The glass antenna applied to the vehicle as claimed in claim 1, wherein: the radiator is of an annular structure and comprises a plurality of dipoles which are periodically distributed and/or uniformly distributed.

4. A glass antenna for vehicle use according to claim 3, wherein: the tail ends of the dipoles are connected with one end of an impedance converter through a power divider, the other end of the impedance converter is connected with a ground plate, an adjusting gap is formed in the ground plate, and the microstrip feeder line is in coupling connection with the radiator gap through the adjusting gap.

5. A glass antenna for vehicle use according to claim 3, wherein: the number of the dipoles is three, and the interval between every two adjacent dipoles is 120 degrees.

6. A glass antenna for vehicle use according to claim 3, wherein: the number of the dipoles is four, and the interval between every two adjacent dipoles is 90 degrees.

7. A glass antenna for vehicle use according to claim 3, wherein: the balun structure comprises a plurality of balun elements, the number of balun elements corresponding to the number of dipoles.

8. The glass antenna applied to the vehicle as claimed in claim 4, wherein: the tail ends of the plurality of balun units are connected with the output end of the phase controller, the input end of the phase controller is connected with one end of the impedance converter, the other end of the impedance converter is connected with a first microstrip feeder line, and the first microstrip feeder line is in coupling connection with the radiator gap through the adjusting gap.

9. The glass antenna applied to the vehicle as claimed in claim 8, wherein: the balun unit is in the shape of

10. A glass antenna for vehicle use according to any one of claims 1 to 9, wherein: the glass is laminated glass and comprises inner-layer glass, a middle layer and outer-layer glass; the balun structure is arranged between the inner layer glass and the outer layer glass, and the antenna unit is arranged on the outer surface of the inner layer glass.