WO2018171912A1

WO2018171912A1 - Antenna device

Info

Publication number: WO2018171912A1
Application number: PCT/EP2017/073788
Authority: WO
Original assignee: Hirschmann Car Communication Gmbh
Priority date: 2017-03-24
Filing date: 2017-09-20
Publication date: 2018-09-27
Also published as: CN106953165A

Abstract

The invention relates to an antenna device comprising an antenna cover (1) and a base mounting (2). The aforementioned antenna cover (1) is secured to the base mounting (2) and forms a water-tight cavity, and a receiver antenna component is provided within the aforementioned water-tight cavity. The aforementioned receiver antenna component comprises an antenna element (3), a coil (4), an antenna mounting (5) and a reinforcing base (6), and the aforementioned antenna mounting (5) and the reinforcing base (6) are secured to the base mounting (2). The aforementioned antenna element (3) is attached to the antenna mounting (5) so as to be connected to the coil (4). The aforementioned coil (4) is connected to the reinforcing base (6), and the aforementioned antenna element (3) is an integral structure which is achieved by a construction with a non-electrically conductive material using a galvanization process. In comparison to the prior art, the invention has advantages such as a flexible structure, a high degree of space efficiency, low production costs, etc.

Description

DESCRIPTION

antenna device

Technical area

The present invention relates to an antenna device in the field of devices provided on vehicles.

State of the art

At present, in the field of on-vehicle devices for application to radio reception (for example AM / FM, DAB, TV, etc.) for the design of the antennas mainly two major embodiments are provided: a concept is integrated on the rear window provided, wherein a common use of Heating wires done. The other conception is an embodiment that is integrated into a fin. Because of the low frequency range for the antenna application and the relatively extensive requirements for the space for realizing the antenna functions, the former design is more aesthetically pleasing compared to the latter concept. However, at the stage of development, different developments are required for the different vehicle types, which causes long development cycles and relatively high costs. In the latter conception, however, there is a restriction of optics in terms of spatial requirements and the difficulties in terms of functional properties and technological realization are relatively high. However, one and the same concept can serve as a platform product, with the application being possible for different types of vehicles without a necessary modification of the design. This means extraordinary advantages in terms of development investment and serial cost. Presently, a radio receive antenna and a GNSS positioning antenna are provided in the fins, in addition, a 4G / 3G / 2G antenna is provided, for 4G MIMO two antennas are required. The addition of new functions results in further compression of the space available for each antenna within the fin, as well as minimizing the interference between the respective antennas.

For the well-known finned antennas provided within fins, mainly spiral rod antennas or spiral magnetic antennas, metal screen antennas, PCB antennas, etc. are used. In the first type, the functional properties are relatively inadequate and the entire upper space within the fin is stressed, which means a tremendous impact on the arrangement of the remaining antennas. In the second type of antenna, a support in the form of a base plate or the like is required, wherein by means of an induction coil to increase the functional properties, which makes the technological realization relatively complicated and takes up a lot of space. In the metal screen antenna element, it is easy to deform during production and transport with high space requirements of the entire antenna element. The third type of antenna is easy to implement but does not provide ideal performance.

Content of the invention

The object of the present invention is to overcome the shortcomings of the prior art by providing an antenna device of flexible construction, high space efficiency and low cost. The present invention describes a new way of realizing the antenna, wherein according to different needs the application for different frequency ranges or for a combination of several frequency ranges is possible. The object of the present invention can be realized by the following technical conception:

An antenna apparatus comprising an antenna hood and a base support, wherein the above-mentioned antenna hood is fixed to the base support and forms a waterproof cavity, wherein within the above-mentioned waterproof cavity, a receiver antenna component is provided, wherein the above-mentioned receiver antenna component comprises an antenna element, a A coil, an antenna holder, and an amplifier base plate, wherein the above-mentioned antenna holder and the amplifier base plate are fixed to the base holder, wherein the above-mentioned antenna element connected to the coil is attached to the antenna holder, wherein the above-mentioned coil is connected to the amplifier base plate it is in the above-described antenna element is a realized by formation of non-electrically conductive material by galvanization integrated construction.

The above-mentioned coil is a variable-turn coil.

The input end of the above-mentioned coil is connected to the output end of the above-described antenna element, and the output end of the coil is connected to the input end of the amplifier base plate by soldering.

The above-mentioned non-electrically conductive material includes ABS, PC or PP.

The electroplating technology used for the above-described antenna element includes drum galvanization, gilding or tampon plating. The metallic material of the plating layer used in the plating of the above-described antenna element comprises one or more of copper, tin, nickel and chromium.

The above-mentioned antenna hood is fixed to the base holder by positioning bolts and screws, and a seal ring is provided at the joint of the antenna hood and base holder.

At the above-mentioned antenna holder, a clamping opening connected to the base holder is provided.

Compared with the prior art, the present invention has the following advantages:

1. In the prior art metal plate antenna elements, there are problems such as large dimensional variations, low precision, high space requirements, etc. The present invention provides a new technology for realizing the antenna element using non-electrically conductive material in view of the above problems. including, but not limited to, ABS, PC, PP, etc.), which after forming by using plating technology (including, but not limited to, drum galvanization, rack galvanization, tampon plating, etc.) Realization is carried out using material having good electroconductive properties for the plating layer (including, but not limited to, copper, tin, nickel, chromium, etc.), so that an effective reduction in dimensional deviation as well as an increase in precision were made that It takes too much space in the assembly of the Vorhaltens, which increases the space efficiency.

2. There is a flexible and variable training of Antenneneiements with good coordination with the antenna cover and maximum use of room height and inner space and maximum increase in the functional properties of the antenna. 3. The antenna element is attached to the base holder with the lower part connected to the coil. By increasing or decreasing the number of turns of the coil, resonance of the antenna element may be within the required frequency range.

4. Unlike the prior art metal sheet bending technology, the antenna of the present invention can be extended to higher frequency ranges and applications (including, but not limited to, cellular antenna, keyless entry, etc.) while maintaining the same Application for sending and receiving is possible.

5. The antenna element has an extremely high conformity in series production and does not easily undergo deformation during packaging and transportation, while metal shield antenna elements of the prior art have relatively large deviations in the design and easily deform during packaging and transportation.

6. The steps of assembly are simple, which increases the production efficiency and lowers the manufacturing cost.

7. The modulated functions allow the integration of radio receiver antennas, cellular antennas, GNSS antennas etc.

Explanation of the illustration

Figure 1 is an illustration of the construction of the present invention.

Reference symbol in Figure 1: 1. Antenna cover, 2. Basic support, 3rd antenna element, 4th coil, 4a. Input end, 4b. Output end, 5th antenna mount, 5a. Terminal opening, 6. Amplifier base plate, 7. Second antenna,

8. Fourth antenna, 9th LNA amplifier, 10th third antenna. Practical embodiments

The following is a detailed description of the present invention with reference to the accompanying drawings and practical examples. The present practical embodiments realize the present invention based on its technical conception, and concrete practical examples and handling operations are given without the scope of the present invention getting any limitation by these practical embodiments.

Practical embodiment 1

As shown in Figure 1, the present practical embodiment provides an antenna device comprising an antenna hood 1 and a base holder 2. In the present practical embodiment, the antenna hood 1 is formed into a fin shape. The antenna hood 1 is fixed to the base holder 2 and forms a watertight cavity with a receiver antenna component provided within the above-mentioned waterproof cavity, the above-mentioned receiver antenna component comprising an antenna element 3, a coil 4, an antenna holder 5 and an amplifier base plate 6, wherein the antenna holder 5 and the amplifier base plate 6 are fixed to the base holder 2, the antenna element 3 connected to the coil 4 being attached to the antenna holder 5, the coil 4 being connected to the amplifier base plate 6 Antenna element 3 is a realized by galvanization after formation of non-electrically conductive material integral construction. The overall design concerned may be tailored to the usable space overall according to the required functional property design. Here, the non-electrically conductive material includes ABS, PC, PP, etc., without being limited thereto. Electroplating technology includes, but is not limited to, drum galvanization, rack galvanization, tampon-grafting, and the like. The Metallmateriai of Galvanization layer comprises one or more of copper, tin, nickel, chromium, etc., without being limited thereto. The concept of the antenna device according to the present invention can maximize the inner height and the space of the antenna dome with the addition of functions and enhancement of the functional characteristics.

The antenna hood 1 is fixed to the base holder 2 by positioning bolts and screws, and at the joint of the antenna hood 1 and base holder 2, a sealing ring is provided, thereby achieving the waterproof effect. At the antenna holder 5, a terminal opening 5a connected to the base holder 2 is provided. The input end 4a of the coil 4 is connected to the output end of the antenna element 3, and the output end 4b of the coil 4 is connected to the input end of the amplifier base plate 6 by soldering. The output end of the antenna element 3 may be provided on the head part, the lower part or any other part of the antenna element as needed. The coil 4 may be provided horizontally, vertically or in any other way connected between the antenna element 3 and the amplifier base plate 6. The coil 4 may be secured by a provided on the antenna mount 5 clamp. The coil 4 may be a variable-turn coil, wherein by increasing or decreasing the number of turns, resonance of the antenna element is effected within the required frequency range.

The principle of operation of the above-mentioned antenna device is shown below: The signal is transmitted via radio waves and the antenna element and the coil are tuned to a corresponding frequency range to convert the radio-electric-wave received by induction into icro-current signals and to the amplifier base plate 6 of the downstream low-noise amplifier transferred to. The amplifier base plate 6 first makes an impedance adjustment of the signal to achieve a flat frequency response and then to amplify and output the signal. Practical embodiment 2

As shown in Figure 1, the antenna element 3 in the antenna device according to the present practical Ausführungsbeiispie! a hollow, stepped construction obtained from non-electrically conductive material by molding in a mold. The outer surface of the respective step construction may be a straight surface or a curved surface, as well as a shielded structure on all four sides or a construction with opening on one or more sides. Otherwise, there is agreement with the practical embodiment 1.

Practical embodiment 3

As shown in Fig. 1, in the antenna device of the present practical embodiment, the antenna element 3 is a hollow stepped structure obtained from non-electrically conductive material by molding in a mold. As required, a groove or notch is provided on the respective stepped construction. Otherwise, there is agreement with the practical Ausführungsbeispie! Second

Practical embodiment 4

As shown in FIG. 1, in the antenna device according to the present practical embodiment, a second antenna 7 and a third antenna 10 are provided inside the waterproof cavity, and the second antenna 7 operates to send and receive a cellular signal, while the third antenna 10 in operation, serves to receive a cellular signal. The second antenna 7 and the third antenna 10 are respectively provided on the two sides of the antenna holder 5 and fixed vertically to the Verstärkerbasispiatte 6. In the present practical embodiment, the second antenna 7 is a 4G main / 3G / 2G antenna and the third antenna 10 is a 4G diversity antenna. Otherwise, there is agreement with the practical embodiment 1. Practical Embodiment 5

As shown in Figure 1, in the antenna apparatus of the present invention, a fourth antenna 8 is provided inside the waterproof cavity, and the fourth antenna 8 is fixed to the base holder 2 and, in use, serves to receive a satellite navigation signal. In the present practical embodiment, the fourth antenna 8 is a GNSS ceramic plate antenna adhered to the low-noise LNA amplifier 9, the LNA amplifier 9 being fixed to the base holder 2. Otherwise, there is agreement with the practical Ausführungsbeispiei. 1

In the foregoing, a detailed description has been given of preferred practical embodiments of the present invention. It should be understood that one skilled in the art may make numerous changes and modifications without the aid of creativity in accordance with the spirit of the present invention. All technical concepts obtained by a person skilled in the relevant technical field according to the idea of the present invention by logical analysis, derivation or limited experiments fall within the scope of the claims.

Claims

Hirschmann Car Communication GmbH, Neckartenzlingen PATENT APPLICATIONS Antenna device

An antenna apparatus comprising an antenna hood (1) and a base supporter (2), wherein the above-mentioned antenna hood (1) is fixed to the base support (2) and forms a watertight cavity, wherein within the above-mentioned waterproof cavity, a receiver antenna component is provided, wherein the above-mentioned receiver antenna component comprising an antenna element (3), a coil (4), an antenna holder (5) and an amplifier base plate (6), wherein the above-mentioned antenna holder (5) and the amplifier base plate (6) the base holder (2) are fixed, the above-mentioned antenna element (3) being connected to the coil (4) attached to the antenna holder (5), the above-mentioned coil (4) being connected to the amplifier base plate (6) in that the antenna element (3) described above is a non-electric one after being formed conductive material realized by galvanization is holistic construction.

2. Antenna device according to claim 1, characterized in that it is in the above-mentioned coil (4) is a coil with a variable number of turns.

An antenna device according to claim 1, characterized in that the input end (4a) of the above-mentioned coil (4) is connected to the output end of the above-described antenna element (3), the output end (4b) of the coil (4) being soldered by the input end of the amplifier base plate (6) is connected.

4. Antenna device according to claim 1, characterized in that the above-mentioned non-electrically conductive material comprises ABS, PC or PP.

5. Antenna device according to claim 1, characterized in that the galvanization technology used for the above-described antenna element (3) comprises drum galvanization, rack galvanization or tampon plating.

An antenna device according to claim 1, characterized in that the metal material of the plating layer used in the plating of the above-described antenna element (3) comprises one or more of copper, tin, nickel and chromium.

7. Antenna device according to claim 1, characterized in that the above-mentioned antenna hood (1) by positioning bolts and screws to the base holder (2) is fixed, wherein at the junction of the antenna hood (1) and base holder (2) a sealing ring is provided.

8. Antenna device according to claim 1, characterized in that on the above-mentioned antenna holder (5) with a base holder (2) connected to the clamping opening (5a) is provided.