DE102013219214A1 - Radom - Google Patents

Abstract

The invention relates to a radome with a planar base body with a peripheral border with a front side facing away from a radar device can be arranged and with a rear side facing a radar device can be arranged, wherein the flat body is formed with a protruding rib.

Description

Technical area

The invention relates to a radome, in particular according to the preamble of claim 1.

State of the art

Radomes are cover elements or cover plates which cover a transmitter emitting radar waves or also a receiver receiving radar waves. These radomes are used particularly in motor vehicles to protect such transmitters of anti-static warning radar systems, which are arranged in the vehicle front or rear of the vehicle, against the effects of the weather and damage, for example against falling rocks. Such radomes are for example by the DE 198 19 709 A1 known.

A radome is substantially transparent to electromagnetic radiation in the long wavelength range, particularly in the microwave range, so that it does not cause distortion of the emitted beams, which would otherwise result in misinterpretation of the received beams.

However, some transmitters of radar waves have the property of emitting the radiation in a very focused manner, so that an opening angle of the radiation of the radar radiation which is relatively narrow can be generated in the azimuth. As a result, the power level of the radiation, ie its amplitude, is limited at an azimuth angle of ± 90 °.

Presentation of the invention, object, solution, advantages

It is the object of the invention to provide a radome, by means of which an improved level of performance can be achieved with a larger azimuth angle.

The solution of the problem is achieved with the features of claim 1.

An embodiment of the invention relates to a radome with a flat base body with a peripheral border with a front facing away from a radar device can be arranged and with a rear side, which can be arranged facing a radar device, the planar body on its back with a protruding Rib is formed. This allows radar beams emitted by a radar to strike the rear of the radar. The rib causes the radar beams to be partially coupled directly into the radome and decoupled from the radome only at the boundary, while another portion of the radar beams passes directly through the radar. As a result, the spatial distribution of the emitted radar radiation changes because the coupled radar beams run in the radome and are decoupled at the edges and therefore the spatial distribution of the radiation is changed. As a result, a higher radiation power or radiation amplitude can be achieved at a higher azimuth angle.

It is particularly advantageous if the flat base body has a transition region, with which it is connected to the peripheral border, wherein the flat body is substantially flat and the transition region is formed protruding from the planar body. Thus, the body can be easily adapted to a housing o. Ä. And connected.

It is particularly advantageous if the transition region projects in a curved manner. Thus, a simple coupling can be provided to a housing.

It is also advantageous if the transition region is substantially arched approximately approximately a quarter circle below. This results in a smooth transition and a tear-off edge on the outer edge of the transition region, whereby the radar beams can be well decoupled from the radome at the edge again. Alternatively, the transition region can also be curved elsewhere. Furthermore, alternatively, the transition region may also be formed as a sharp edge.

It is also expedient for the rib to linearly connect two first opposite sides of the border. Thereby, the full width of the radome can be used for the coupling of the radar beams by means of the rib.

It is also advantageous if the rib is arranged linearly and at a distance between two second opposite sides of the border. In this case, the rib is preferably aligned parallel with the two second sides. In another embodiment, the rib may also be arranged elsewhere to the sides, as in particular in a non-rectangular design.

It is also particularly advantageous if the distance of the rib to a first of the two second opposite sides is greater than the distance of the rib to a second of the two second opposite sides. As a result, the coupling into the radome can be optimized, so that the radiation of the radiation coupled out of the radar can likewise be optimized as required, because then the rib can be arranged at offset of the antenna above the antenna. Alternatively, the rib can also be arranged centrally with a suitable arrangement of the antenna.

Furthermore, it is expedient if the flat base body is formed substantially rectangular. Alternatively, it may also have a different shape, such as square, round, oval, polygonal, etc.

It is also advantageous to warm the rib projecting in the direction of the protruding transition region. As a result, the rib also protrudes toward the rear side in the direction of the radar device, so that the radiation can couple in the region of the vertex of the rib.

It is also advantageous if the rib has two opposite concave side edges. Thereby, the apex is formed as the projecting portion between the concave side flanks. There, the apex is preferably rounded.

Further advantageous embodiments are described by the following description of the figures and by the subclaims.

Brief description of the drawings

The invention will be explained in more detail on the basis of at least one embodiment with reference to the drawings. Show it:

1 a view of the radome from the back,

2 a view of the radome from the front,

3 a section through the radome according to line II of 2 .

4 a side view of the radome,

5 an enlarged section according to area A of 3 .

6 a diagram.

Preferred embodiment of the invention

The 1 shows the radar 1 from the back 2 while the 2 the radome from the front 3 shows. The radar 1 is doing so with a flat body 4 with a circumferential border 5 educated. The radome 1 is with its flat body 4 essentially rectangular, with the corners 6 are rounded. Alternatively, the radar may also take on a different shape, such as round, oval or square. Also, the radar may be polygonal, such as triangular, pentagonal, hexagonal or octagonal.

The backside 2 is facing the operation of the radar to a radar device arranged behind it. The front side points in the opposite direction and points away from the radar. The radar device is not shown in the figures.

In the 1 It can be seen that the flat body on its back 2 with a protruding rib 7 is trained. The rib 7 is from the back 2 before, projecting in the direction of the radar device arranged behind it.

The rib 7 is linear and connects two first opposite sides 8th . 9 the border 5 , This is the rib 7 approximately perpendicular to the two sides 8th . 9 aligned. Also is the rib 7 approximately parallel to two other second pages 10 . 11 the border 5 arranged. To these two sides 10 . 11 is the rib 7 spaced apart, with the rib 7 closer to the page 10 is arranged as the opposite side 11 , The 1 and 3 show this.

In a further embodiment, the rib 7 also in the middle between the pages 10 . 11 be arranged.

In the 3 and 5 it can be seen that the rib 7 with two opposite concave side edges 12 . 13 and an intermediate vertex 14 is trained. The vertex 14 is the essentially straight back of the rib 7 ,

In the 3 and 4 it can be seen that the flat basic body 4 a transition area 15 has, with which he with the circumferential border 5 is connected, wherein the flat body 4 is substantially planar and the transition region 15 from the flat body 4 is formed above.

The 3 and 4 show that the transition area 15 protruding arched, as in particular substantially approximately a quarter circle is curved below.

The 5 shows a diagram in which in each case two curves of a radiation amplitude in dependence of an angle of the elevation or the azimuth are shown in comparison. The cure 20 and the curve 21 set the amplitude of the radar beams for an application of a radome without rib or with rib according to the invention as a function of an angle for the elevation. The curve 22 and the curve 23 represent the amplitude of the radar beams for an application of a radome without rib or rib according to the invention as a function of an angle for the azimuth. It can be seen that the curve 23 represents a much wider distribution of the amplitude than the curve 22 , This means that a broader radiation is caused as a function of the azimuth angle due to the rib. You can see that the curve 21 represents a slightly narrower amplitude distribution than the cure 20 , This means that a narrower-band emission is effected as a function of the elevation angle due to the rib. This leads to a broadening of the signal at the azimuth angle, while the distribution in the elevation narrows. This is effected because a portion of the radar beams by means of the rib 7 be coupled into the radome, which are decoupled at the peripheral edge again. In this case, a proportion of about 5 to about 50% can be coupled into the radome, this process causes a redistribution of the radiation from the radome in comparison to a radome without rib, in which the injected radiation fraction is very low to 0.

The radome is advantageously made of a plastic material, such as a plastic with or without glass fiber content. For example, a material with PBT + PC + 20% glass fiber content can be used. Also, other materials can be suitably used. On the front, the radome can be coated as varnished.

LIST OF REFERENCE NUMBERS

1

Radom

2

back

3

front

4

body

5

border

6

corner

7

rib

8th

first page

9

first page

10

second page

11

second page

12

side flank

13

side flank

14

vertex

15

Transition area

20

Curve

21

Curve

22

Curve

23

Curve

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19819709 A1 [0002]

Claims (10)

Radom with a flat body with a circumferential border with a front facing away from a radar device can be arranged and with a back, which can be arranged facing a radar device, characterized in that the flat body is formed on its back with a protruding rib , Radom according to claim 1, characterized in that the flat base body has a transition region, with which it is connected to the peripheral border, wherein the flat body is substantially planar and the transition region is formed protruding from the planar body. Radome according to claim 2, characterized in that the transition region protrudes curved or forms a sharp edge. Radome according to claim 3, characterized in that the transition region is curved substantially approximately a quarter circle below. Radome according to one of the preceding claims, characterized in that the rib linearly connects two first opposite sides of the border. Radome according to one of the preceding claims, characterized in that the rib is arranged linearly between two second opposite sides of the border. Radome according to one of the preceding claims, characterized in that the distance of the rib to a first of the two second opposite sides is greater than or equal to the distance of the rib to a second of the two second opposite sides. Radome according to one of the preceding claims, characterized in that the flat base body is formed substantially rectangular. Radome according to one of the preceding claims, characterized in that the rib protrudes in the direction of the above transition region. Radome according to one of the preceding claims, characterized in that the rib has two opposite concave side edges.

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