DE102013104677A1 - Flexible shortenable antenna - Google Patents

Abstract

The invention relates to a flexible antenna (1) for electromagnetic waves for attachment to an outer surface of a body (10) in the circumferential direction, the antenna (1) having an antenna connection (14) and at least one antenna element (12) connected to the antenna connection (14). for electromagnetic waves, the antenna (1) being designed with at least one separation point (20) at which the antenna (1) can be shortened in the circumferential direction by cutting off at least part of an antenna element (12).

Description

The present invention relates to a flexible electromagnetic wave antenna for attachment to an outer surface of a body in the circumferential direction, the antenna having an antenna terminal and at least one electromagnetic wave antenna element connected to the antenna terminal.

Electromagnetic waves can be used to transmit information. In this case, different transmission methods are known in which the electromagnetic waves can be transmitted both wired and wireless. In order to transfer an electromagnetic wave from a wired medium into a wireless medium, an antenna is required. Basically, each antenna can be both received and sent. For simplicity, only the transmission mode will be considered below.

There are different types of antennas in the prior art. Those which emit the wave evenly in all spatial directions, also called omnidirectional or isotropic antennas, and those which selectively send the waves in one or more directions, also called directed antennas. The characteristic used is the directional characteristic.

The gain of an antenna in the case of reception is the logarithmic ratio of the received powers with respect to a reference antenna, generally the isotropic antenna. The gain of an antenna depends on the directional characteristic.

The best known in a plane omnidirectional antennas are rod-shaped antennas, which usually have a cable feed to the foot. In order to allow for optimal propagation of the wave, obstacles should be as far away from the antenna as possible. Therefore, these antennas are usually installed in an exposed position. For this purpose, one often makes use of the presence of masts and mounted the antenna at the top of such a mast. If there are no suitable masts in a desired location, the masts can also be set up explicitly for the attachment of the antenna.

Due to the exposed position of the omnidirectional antennas, there is a high risk of damage due to overvoltages, for example due to lightning strikes. In addition, due to environmental conditions, it may not be possible to mount the antenna in a desired position that allows for omnidirectional radiation.

Furthermore, planar or flat flexible antennas are known, which can be attached to a substantially arbitrarily shaped body. These are usually special antennas that are adapted to the specific body, or universal antennas whose antenna properties are not suitable for every use.

Based on the above-mentioned prior art, the object of the invention is thus to specify an antenna of the above-mentioned type whose properties allow flexible use, which is flexible and easy to install, which has a low susceptibility to overvoltages, and which is easy to manufacture is.

The object is achieved by the features of the independent claims. Advantageous embodiments of the invention are specified in the subclaims.

Thus, according to the invention, there is provided a flexible electromagnetic wave antenna for attachment to an outer surface of a body in the circumferential direction. The antenna has an antenna terminal and at least one electromagnetic wave antenna element connected thereto. Furthermore, the antenna is designed with at least one separation point at which the antenna can be shortened in the circumferential direction by separating at least a part of an antenna element.

The basic idea of the present invention is thus to design the flexible antenna in such a way that a single, prefabricated antenna type can be attached to the outer surfaces of different bodies. This creates a universal antenna that allows for flexible use. For example, the antenna can be attached by length reduction to bodies with different outer circumferences. In this case, the outer circumference can be completely covered by the antenna, wherein overlaps of the antenna, which can lead to disturbances in the radiation of the wave can be eliminated by shortening the antenna. The flexibility of the antenna can be attached to different bodies. In contrast to rod antennas, the antenna can be easily mounted anywhere such as a central area of posts or masts. Thus, the antenna can be mounted below a highest point of the body, so that only a slight susceptibility to overvoltages is given. The mast itself is no obstacle to the antenna.

The number and arrangement of the separation points is freely selectable, whereby the antenna can be used more flexibly with an increasing number of separation points. In principle, the separation points can be arranged and configured as desired. Usually they are Separation points arranged transversely to the circumferential direction and executed to allow a shortening of the antenna in the circumferential direction. In principle, the antenna can be shortened at its two ends in the circumferential direction. Advantageously, however, the antenna can only be shortened at one end.

The antenna connection can be formed at any point of the antenna, so that one or more antenna elements are arranged on both sides of the antenna connection. Preferably, the antenna is designed with a strain relief device to relieve the antenna connection and protect it from damage.

The antenna is suitable for attachment to arbitrarily shaped outer surfaces. The bodies may, for example, have an annular or elliptical cross section.

In an advantageous embodiment of the invention, the antenna has a carrier layer with which the antenna can be attached to the body, wherein the carrier layer is a self-adhesive layer. The carrier layer thus allows a simple attachment of the antenna to the body by gluing. This is particularly suitable, for example, for attachment to metallic bodies or bodies made of plastic.

In an advantageous embodiment of the invention, the antenna has an insulation layer, with which the antenna is electrically isolatable with respect to the body, wherein the insulation layer extends beyond the antenna connection or the outermost antenna element on its side opposite in the circumferential direction of the at least one separation point. The insulating layer makes it possible that the antenna can be attached to any body, including on conductive bodies. By extending the insulation layer beyond the antenna connection or the outermost antenna element, the insulation layer can bring about reliable isolation of the antenna itself, for example if an overlapping of the two ends of the antenna should result when the antenna is attached to the body. Particularly preferably, the insulating layer is formed integrally with the carrier layer, that is, the insulating layer is designed as a self-adhesive insulating layer.

In an advantageous embodiment of the invention, the antenna is designed such that the antenna is designed opposite to its applied to the body side with a cover layer. The cover layer forms a protection of the antenna from environmental influences, in particular from moisture. Contact of electrically conductive components of the antenna with moisture is prevented by the cover layer.

In an advantageous embodiment of the invention, the antenna is designed such that the antenna has a conductive base layer, a structural layer with the at least one antenna element and an intermediate insulating intermediate layer therebetween. This structure can be easily produced by, for example, applying the structural layer to the insulating interlayer. For this purpose, for example, the antenna elements can be applied directly to the intermediate layer. The structural layer does not have to be a continuous layer with a uniform material thickness. In addition to the antenna elements, the structure layer may also have a conductor structure for connecting the antenna structure to the antenna connection. The antenna elements can be designed as meander-shaped structures. Preferably, the base layer is positioned on the side facing the body in the mounted state. The base layer, the antenna elements and the optional conductor structure are preferably made of copper.

In an advantageous embodiment of the invention, the antenna is designed such that the antenna has a plurality of antenna elements which are connected via a conductor structure to the antenna terminal, wherein the at least one separation point divides the conductor structure. By shortening the antenna thus at least one antenna element is separated from the antenna. The individual antenna elements can be connected to each other and / or to the conductor structure in different ways, for example, in parallel or in series. In a chain circuit of the transmitting units, a traveling wave antenna is formed.

In an advantageous embodiment of the invention, the antenna is designed such that the antenna has at least one antenna element which extends in the circumferential direction, wherein the at least one separation point divides the antenna element. By way of example, the antenna element can be designed with a meandering structure, this structure being interrupted and partially separated by the shortening of the antenna. The antenna may have an antenna element in the circumferential direction starting from the antenna connection in one or both directions.

In an advantageous embodiment of the invention, the antenna is designed such that the antenna is designed at the at least one separation point with a separation mark. This makes it easier to shorten the antenna. At the same time it is ensured that the antenna is shortened only in those places, which do not lead to any unwanted change of their characteristics. The markings are preferably optical and / or haptic markings.

In an advantageous embodiment of the invention, the antenna is designed as a leak or leaky waveguide, the leak or leaky waveguide arranged in an insulating medium conductor and an outer shield surrounding the insulating medium, and in the screen at least one leak to the radiation of the electromagnetic wave is trained. The leak radiator or leaky-waveguide can be designed with various cross sections, for example, an annular cross section or a rectangular cross section. The leak or leaky waveguide may have different leaks performed, for example, as slots in the circumferential direction or as a circumferential leak around the head. The antenna can also be designed as a slot antenna.

In an advantageous embodiment of the invention, the antenna is designed such that the antenna terminal is designed for connection of the antenna from the side of the body. Thus, for example, the antenna may be attached to a tubular body and connected to a cable routed in the body. Thus, no cable must be routed to an outside of the body and an exposed connection of the cable with the antenna connection is eliminated. A cover and possibly sealing the antenna connection to the outside by the antenna itself.

In an advantageous embodiment of the invention, the antenna is designed such that it has a directional characteristic for the emission of the electromagnetic wave. Thus, the antenna can be used to generate specific transmission lobes to radiate the energy of the wave in a desired manner. For example, the antenna may be designed for uniform radiation in the circumferential direction, i. an emission transverse to the circumferential direction is reduced. The directional characteristic can be formed both by the configuration and / or the arrangement of the at least one antenna element.

In an advantageous embodiment of the invention, the antenna is designed such that the antenna is a film antenna, and the layers are designed as layer films. Thus, the antenna can be easily manufactured, for example, by making individual films separately and interconnecting them. The bonding preferably takes place by gluing or welding.

The invention will be explained in more detail with reference to the accompanying drawings with reference to preferred embodiments.

Show it

1 1 is a schematic representation of an antenna according to a first embodiment with a plurality of antenna elements,

2 a schematic sectional view of the antenna 1 in the area of their antenna connection,

3 a schematic representation of the antenna 1 on a cylindrical body,

4 a schematic plan view of a mast with the antenna 1 and emission lobes of the antenna elements,

5 a schematic perspective view of the arrangement 4 , where only two transmission lobes are shown,

6 the presentation 4 as a schematic sectional view, wherein only three transmission lobes are shown,

7 1 is a schematic representation of an antenna according to a second embodiment with a plurality of antenna elements,

8th a schematic perspective view of the antenna 7 on a mast with emission lobes of the antenna elements, wherein only three emission lobes are shown,

9 a schematic representation of an antenna according to a third embodiment for attachment to a mast, and

10 a schematic representation of an application example of the antennas with a transmission between antennas of multiple masts.

The 1 to 3 show an antenna according to the invention 1 electromagnetic wave according to a first preferred embodiment. The antenna 1 is as a flexible film antenna with a plurality of layers 2 . 3 . 4 . 5 . 6 , which are welded together in this embodiment executed. The antenna 1 is still for attachment to a body 10 , which is exemplified here a lamppost with an annular cross-section, executed, the antenna 1 is for attachment to the mast 10 is formed in the circumferential direction.

The structure of the antenna 1 is in detail in 2 shown. The antenna comprises a self-adhesive carrier layer 2 with which the antenna 1 on the mast 10 attachable. The carrier layer 2 is made of an electrically insulating material and thus acts as an insulating layer, which is the antenna 1 electrically isolated from the mast.

Furthermore, the antenna comprises 1 a conductive base layer 3 made of copper, a structural layer 4 , as well as an intervening insulating interlayer 5 made of plastic. At her the carrier layer 2 opposite side, the antenna has a cover layer 6 on, which is made of an insulating plastic and as a film on the structural layer 4 is applied.

The structural layer 4 has in this embodiment a plurality of individual antenna elements 12 for electromagnetic waves. The antenna elements 12 are each designed as meandering structures and arranged in the circumferential direction one behind the other. Furthermore, the structural layer comprises 4 a ladder structure 13 which the antenna elements 12 with each other and with an antenna connection 14 combines.

The antenna connection 14 that in detail in 2 is shown comprises a coaxial line section 15 for connection to a coaxial cable 17 , Accordingly, the base layer with an outer conductor 18 the antenna elements 12 about the ladder structure 13 with an inner conductor 19 of the coaxial cable 17 connected.

Furthermore, the antenna is 1 with a plurality of separation points 20 transverse to the circumferential direction at which the antenna 1 in the circumferential direction by separating at least one antenna element 12 can be shortened. The separation points 20 are thus positioned to be the antenna 1 each in the area of their ladder structure 13 divide. The separation points 20 are in 1 shown and with separation marks 21 executed. The separation marks 21 are as arrows on the top layer 6 printed.

The carrier or insulation layer 2 has in the circumferential direction of the separation points 20 opposite end to an extent that exceeds the extent of the base layer 3 enough, as in 1 is recognizable. When attaching the antenna 1 on the mast 10 becomes the carrier layer 2 with her over the base layer 3 reaching end at least partially overlapping on the cover layer 6 applied.

At the antenna 1 of the first embodiment is the antenna terminal 14 in a central region of the antenna 1 designed so that multiple antenna elements 12 on both sides of the antenna connector 14 are arranged. The antenna connection 14 extends through the carrier layer 2 for connecting the antenna 1 from the side of the mast 10 ,

The antenna elements 12 have in this embodiment, a directional characteristic for the radiation of the electromagnetic wave, as in the 4 to 6 is shown. Accordingly, at each antenna element 12 a transmission lobe 22 generated to radiate the energy of the wave in a desired manner. The transmission lobes 22 are equally spaced in the circumferential direction, so that a uniform radiation results in the horizontal direction, while a radiation in the vertical direction is reduced.

An antenna 1 According to a second embodiment is in the 7 and 8th shown. The antenna 1 The second embodiment substantially corresponds to that of the first embodiment. The difference is only in the design of the individual antenna elements 12 that have a common ladder structure 13 parallel to the antenna connection 14 are connected.

An antenna 1 according to a third embodiment is in 9 shown. The antenna 1 The third embodiment is designed as a leaky waveguide in foil form. The leaky waveguide has a conductor 30 who is in an isolation medium 31 is arranged, and an outer screen 32 , the isolation medium 31 surrounds, up. In the screen 32 is a plurality of leaks 33 designed to emit the electromagnetic wave.

10 shows an application example of the antennas 1 the embodiments described above. There are several masts 10 , which are designed here as a lampposts with a radio-controlled control unit for driving the lantern, each having a previously described antenna 1 executed. The control units of adjacent masts 10 are connected by radio. By attaching the antennas 1 with their transmit beams 22 in each case in the direction of adjacent antennas 1 a reliable communication takes place. The antennas of the described embodiments can be combined as desired.

LIST OF REFERENCE NUMBERS

 1

antenna

 2

Carrier layer, insulation layer

 3

base layer

 4

structural layer

 5

interlayer

 6

topcoat

 10

Body, mast

12

emitting unit

 13

conductor structure

14

antenna connection

15

coaxial line section

 17

coaxial cable

 18

outer conductor

19

inner conductor

20

separation point

 21

separation marking

 22

transmission lobe

 30

ladder

 31

insulation medium

32

tube

33

leak

Claims (12)

Flexible antenna ( 1 ) for electromagnetic waves for attachment to an outer surface of a body ( 10 ) in the circumferential direction, wherein the antenna ( 1 ) an antenna connector ( 14 ) and at least one with the antenna connector ( 14 ) connected antenna element ( 12 ) for electromagnetic waves, characterized in that the antenna ( 1 ) with at least one separation point ( 20 ) is executed, on which the antenna ( 1 ) in the circumferential direction by separating at least a part of an antenna element ( 12 ) can be shortened. Antenna ( 1 ) according to claim 1, characterized in that the antenna ( 1 ) a carrier layer ( 2 ), with which the antenna ( 1 ) on the body ( 10 ) is attachable, wherein the carrier layer ( 2 ) is a self-adhesive layer. Antenna ( 1 ) according to one of claims 1 or 2, characterized in that the antenna ( 1 ) an insulation layer ( 2 ), with which the antenna ( 1 ) opposite the body ( 10 ) is electrically isolable, wherein the insulating layer ( 2 ) at its in the circumferential direction of the at least one separation point ( 20 ) opposite side via the antenna connector ( 14 ) or the outermost antenna element ( 12 ) extends. Antenna ( 1 ) according to one of the preceding claims, characterized in that the antenna ( 1 ) opposite to their on the body ( 10 ) to be applied with a top layer ( 6 ) is executed. Antenna ( 1 ) according to one of the preceding claims, characterized in that the antenna ( 1 ) a conductive base layer ( 3 ), a structural layer ( 4 ) with the at least one antenna element ( 12 ) and an intervening insulating interlayer ( 5 ) having. Antenna ( 1 ) according to one of the preceding claims, characterized in that the antenna ( 1 ) a plurality of antenna elements ( 12 ), which have a conductor structure ( 13 ) with the antenna connector ( 14 ), wherein the at least one separation point ( 20 ) the ladder structure ( 13 ). Antenna ( 1 ) according to one of the preceding claims, characterized in that the antenna ( 1 ) at least one antenna element ( 12 ) extending in the circumferential direction, wherein the at least one separation point ( 20 ) the antenna element ( 12 ). Antenna ( 1 ) according to one of the preceding claims, characterized in that the antenna ( 1 ) at the at least one separation point ( 20 ) with a separation mark ( 21 ) is executed. Antenna ( 1 ) according to one of the preceding claims, characterized in that the antenna ( 1 ) is designed as a leak or leaky waveguide, wherein the leak or leaky waveguide one in an isolation medium ( 31 ) arranged conductors ( 30 ) and an outer screen ( 32 ), the isolation medium ( 31 ) and in the screen ( 32 ) at least one leak ( 33 ) is designed to emit the electromagnetic wave. Antenna ( 1 ) according to one of the preceding claims, characterized in that the antenna connection ( 14 ) for connecting the antenna ( 1 ) from the side of the body ( 10 ) is executed. Antenna ( 1 ) according to one of the preceding claims, characterized in that the antenna ( 1 ) has a directional characteristic for the emission of the electromagnetic wave. Antenna ( 1 ) according to one of the preceding claims, characterized in that the antenna ( 1 ) is a foil antenna, and the layers ( 2 . 3 . 4 . 5 . 6 ) are designed as layer films.

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