DE10246607A1 - Electro-chrome radar sensor e.g. for motor vehicle applications, has radar-sensor arrangement provided in forward direction of electromagnetic wave from observed object - Google Patents

Abstract

Electro-chrome radar sensor has a radar sensor arrangement (6,7) and an electro-chrome layer arrangement (1-5). The radar-sensor arrangement (6,7) is provided in the forward direction (8) of an electromagnetic wave leaving an observed object, and in the forward direction of the radar sensor arrangement (6,7) the electro-chrome layer arrangement (1-5) is subordinated. Independent claims are included for: (A) a method for manufacturing an electro-chrome radar sensor; and (B) application of an electro-chrome radar sensor.

Description

The invention relates to an electrochromic radar sensor with a radar sensor arrangement, and with an electrochromic layer arrangement. The invention also relates to a method for producing such a radar sensor, in which first an electrochromic layer arrangement is produced. Finally concerns the invention also uses such an electrochromic Radar sensor.

From the German published application DE 196 22 600 A1 an electrochromic unit is known which is formed by an electrochemical cell with at least two electrodes arranged on a carrier, an electrolyte arranged between the electrodes and an electrochromic material applied to the electrodes.

This electrochromic unit can be For example, in automotive engineering to use incoming electromagnetic To absorb radiation, preferably light. For example, this is for dimmable Return and Outside mirrors and black-out windows to prevent the Exposure to sunlight is desirable. A disadvantage of these electrochromic arrangements, however, is that them for electromagnetic Waves in some wavelength ranges, especially for Radar applications, impermeable are. Therefore, it is currently not possible to put together a radar sensor to combine with an electrochromic glass, for example a mirror.

From the publication US 4,210,357 a rear-view mirror of a motor vehicle is known, in which a radar sensor is integrated. For this purpose, a translucent, curved reflector is provided in front of the mirror, which reflects electromagnetic waves that are common for radar applications. The curvature of the reflector is such that the reflected electromagnetic waves are directed to the radar sensor arranged below the mirror in order to be received and evaluated there. The light passing through the reflector is reflected by the mirror and allows the driver to look backwards. However, the curved reflector has the disadvantage that it is very complex to manufacture and can easily be damaged. The assembly of such a mirror is also very complex since, in addition to the actual mirror, the reflector also has to be installed in the housing of the outside mirror.

From the disadvantages shown above results for the invention the technical problem of having a radar sensor available set that operated together with an electrochromic layer arrangement can be.

The previously derived technical According to the invention, this creates a problem solved, that in the forward direction one originating from an observed object electromagnetic wave the radar sensor arrangement is provided and that in the forward direction of the radar sensor arrangement the electrochromic Layer arrangement is subordinate.

That means that from the radar sensor radar waves emitted are reflected by an object and the reflected waves first hit the radar sensor assembly. Light of the same Object is emitted or reflected, passes through the radar sensor arrangement through on the layer arrangement and can there in the case of a viewing window pass through or be reflected in the case of a mirror.

By arranging the radar sensor arrangement in the forward direction upstream of the layer arrangement, it is possible to use electromagnetic To emit waves in the radar range through the radar sensor arrangement and receive. The electrochromic layer arrangement is for electromagnetic Radar waves essentially impermeable. She points at these wavelength a transmission coefficient of approximately zero. Radar waves can be behind the electrochromic layer arrangement is no longer sufficiently accurate be evaluated. The electrochromic layer arrangement is therefore according to the invention arranged behind the radar sensor arrangement.

In addition to receiving the electromagnetic Waves in the radar range through the radar sensor arrangement make it for electromagnetic Waves possible at least in the visible range up to the layer arrangement to get. There you can these electromagnetic waves, according to the respective application, pass through the electrochromic layer depending on its wavelength or dampened become.

It is preferred that at least the outer layers the layer arrangement is electrically insulating and for electromagnetic waves are transparent in the optical range and in the radar frequency range. Here you can the layers are evaporated or applied in some other way become. For example, with a mirror glass, an outer layer, which is electrically insulating and transparent, can be vapor-deposited.

It is also proposed that at least one of the outer layers the layer arrangement is formed from glass.

According to an advantageous embodiment, it is proposed that the electrochromic layer arrangement is formed as an electrochromic mirror, so that the electromagnetic waves are at least partially reflected. This ensures that, in addition to the radar functionalities, the functionality of a mirror is also used can be. In this case, it is possible for a user, for example, to monitor the area facing away from him optically, using the mirror, and also using radar.

Especially in motor vehicles The supervision of the back room of the vehicle is important, which is why it is proposed that the electrochromic Radar sensor is arranged in a motor vehicle. Here is particularly advantageous if the electrochromic radar sensor in one Rearview mirror and / or an outside mirror is arranged.

To ensure an undisturbed visual perception to be able it is proposed that the radar sensor arrangement for electromagnetic waves is transparent at least in the visible area.

In addition to the advantage of an electrochromic glass, which can be darkened is often too heating is provided in the glass or mirror. In this Allowed to fall but by the filaments or other heating devices that do not affect the radar properties, which is why it is proposed that the radar sensor arrangement be in the forward direction a heating device is arranged downstream.

A planar structure of the layer arrangement, in particular of the mirror, for that often only a small installation space is available, is achieved that the radar sensor assembly has a patch antenna. Here, the patch antenna can, for example be formed in microstrip technology.

Another object of the invention is a process for producing an electrochromic described above Radar sensor, at first an electrochromic layer arrangement is produced and in which a radar sensor arrangement is applied to the electrochromic layer arrangement is, the radar sensor arrangement in the forward direction in front of the electrochromic layer arrangement is arranged.

An additional object of the invention is the use of a previously described electrochromic radar sensor for one Blind spot detection device, a lane change assistant, or a door opening assistant in one Outside mirror of a motor vehicle and / or a front and / or a rear window a motor vehicle. Especially for lane change assistants who to ensure a safe lane change of a vehicle, it is important that the radar sensor arrangement with a low probability of error is working. However, this is only possible if the electromagnetic Waves as made possible according to the invention not damped in the radar range or reflected before they reach the radar sensor. Also a door opening assistant can be controlled by the radar detection so that when you get out of the vehicle in front of other vehicles, bicycles or passers-by are warned and the door may not be opened.

The invention is described below one an embodiment showing drawing closer explained. In the drawing, the single figure shows a structure of an electrochromic according to the invention Radar sensor.

In 1 an electrochromic layer arrangement is shown, which consists of a first glass pane 1 , a reflective, full-surface metallization 2 , an electrochromic medium 3 , a transparent, full-surface metallization 4 and a second sheet of glass 5 is formed. In front of it a radar sensor is provided, which consists of a transparent, partial metallization 6 that on a third pane of glass 7 is applied, is formed. The first pane of glass 1 and the second pane of glass 5 can also be formed from other, electrically insulating and transparent materials. For example, the second layer 5 be evaporated.

Incident light and electromagnetic waves in the radar range hit from the direction of incidence 8th on the arrangement shown. This direction of incidence 8th is the forward direction. Through the glass 1 and the reflective, full-surface metallization 2 which together form a mirror, the incident light is directed towards 9 reflected.

The glass pane 1 and the reflective, full-surface metallization 2 form a first electrode for the electrochromic properties. The transparent, full-surface metallization 4 and the second pane of glass 5 The second electrode for the electrochromic properties is formed from a material other than glass. A voltage applied between these electrodes changes the reflection and transmission properties of the electrochromic medium 3 , whereby damping of electromagnetic waves, preferably in the visible range, but also in the UV range, can be achieved, which leads, for example, to a darkening of the mirror.

The transparent, partial metallization 6 , together with the glass pane 7 , form the radar sensor. Even the glass slides 7 can be made of another material. This is transparent at least for electromagnetic waves in the visible range. The transparent, partial metallization 6 is formed as a patch array, which means that a large number of microstrip patches form the radar antenna, the directional characteristic of which can be set. The patch array is designed so that it can receive at least electromagnetic waves in the millimeter range.

The radar sensor makes it possible to transmit radar waves. Reflected radar waves from objects to be observed can be received in the radar sensor. Because the radar sen is arranged in front of the electrochromic layer arrangement, the radar waves in the arrangement shown are not attenuated or reflected before they are received. Incoming radar waves can be evaluated unhindered by the radar sensor. Incident light waves can pass through the radar sensor and reach the electrochromic layer arrangement.

1

first pane

2

reflective whole-area metallization

3

electrochromic medium

4

transparent whole-area metallization

5

second pane

6

transparent partial-area metallization

7

third pane

8th

incidence direction

9

reflection direction

Claims (11)

Electrochromic radar sensor, with a radar sensor arrangement ( 6 . 7 ), and with an electrochromic layer arrangement ( 1 . 2 . 3 . 4 . 5 ), characterized in that in the forward direction ( 8th ) the radar sensor arrangement of an electromagnetic wave emanating from an observed object ( 6 . 7 ) is provided and that in the forward direction ( 8th ) of the radar sensor arrangement ( 6 . 7 ) the electrochromic layer arrangement ( 1 . 2 . 3 . 4 . 5 ) is subordinate. Electrochromic radar sensor according to claim 1, characterized in that at least the outer layers ( 1 . 5 ) the layer arrangement ( 1 . 2 . 3 . 4 . 5 ) are electrically insulating and transparent to electromagnetic waves in the optical range and in the radar frequency range. Electrochromic radar sensor according to claim 1, characterized in that at least one of the outer layers ( 1 . 5 ) the layer arrangement ( 1 . 2 . 3 . 4 . 5 ) is made of glass. Electrochromic radar sensor according to claim 1, characterized in that the electrochromic layer arrangement ( 1 . 2 . 3 . 4 . 5 ) is formed as an electrochromic mirror, so that the electromagnetic wave is at least partially reflected. Electrochromic radar sensor according to one of the preceding Expectations, characterized in that they are arranged in a motor vehicle is. Electrochromic radar sensor according to one of claims 1 to 3, characterized in that they are in a rear view mirror and / or an outside mirror Motor vehicle is arranged. Electrochromic radar sensor according to one of the preceding claims, characterized in that the radar sensor arrangement ( 6 . 7 ) is transparent to electromagnetic waves, at least in the visible range. Electrochromic radar sensor according to one of claims 1 to 5, characterized in that in the transmission direction ( 8th ) of the radar sensor arrangement ( 6 . 7 ) a heating device is arranged downstream. Electrochromic radar sensor according to one of claims 1 to 6, characterized in that the radar sensor arrangement ( 6 . 7 ) has a patch antenna. Method for producing an electrochromic radar sensor according to one of Claims 1 to 7, in which an electrochromic layer arrangement ( 1 . 2 . 3 . 4 . 5 ) is produced and in which the electrochromic layer arrangement ( 1 . 2 . 3 . 4 . 5 ) a radar sensor arrangement ( 6 . 7 ) is applied, the radar sensor arrangement ( 6 . 7 ) in the forward direction ( 8th ) before the electrochromic layer arrangement ( 1 . 2 . 3 . 4 . 5 ) is arranged. Using an electrochromic radar sensor after one of the claims 1 to 7, for one Blind spot detection device, a lane change assistant, one Door opening Wizard in an outside mirror of a motor vehicle and / or a front and / or a rear window of a motor vehicle.