WO2017121533A1

WO2017121533A1 - Rear-view mirror assembly having optical display for motor vehicles

Info

Publication number: WO2017121533A1
Application number: PCT/EP2016/078974
Authority: WO
Inventors: Peter Krebs
Original assignee: Magna Mirrors Holding Gmbh
Priority date: 2016-01-14
Filing date: 2016-11-28
Publication date: 2017-07-20
Also published as: DE102016200391B3

Abstract

The invention relates to a rear-view mirror assembly (1) for motor vehicles, comprising a mirror base (2) and a mirror head (3), having at least one housing (4), in which a recess for a mirror assembly (5) is formed, wherein the reflectance value of the mirror assembly is configured such that it can be changed by a control device, and wherein the mirror assembly has a glass plate (11) arranged on the front side and an optical cell (7), having an optically active layer (10), and wherein an optical display module (6) is arranged behind the mirror assembly inside the mirror head, so that the light of the optical display module passes through the mirror assembly, and wherein a reflective coating (12) has a light-permeable opening (22) in the region of the optical display module, and the optically active layer is recessed in the region (10a) of the optical display module, and this region contains an optically transparent adhesive (10b).

Description

Rear-view mirror arrangement with optical display for motor vehicles

The present invention relates to a rearview mirror assembly with optical display for motor vehicles.

Background Art Rearview mirror assemblies for motor vehicles have a reflective surface that allows the rearward traffic to be observed. Usually, the rear mirror assemblies are additionally designed dimmable. As a result, a dazzling is avoided by driving behind in the dark driving. In auto-dimming rear-view mirror assemblies measure or capture arranged in the mirror housing

Light sensors the brightness difference between the car forecourt and the rear traffic area. The measured values are then forwarded to an evaluation and control electronics and the reflectivity of the mirror arrangement is changed accordingly. In this case mirror assemblies are used which comprise optical cells. These optical cells may be formed, for example, as liquid crystal cells (LC) or as electrochromic cells (EC). In these mirror arrangements, the reflectivity is changeable when an electric field is applied.

In mirror assemblies with electrochromic cells, the property of electrochromic materials is used to change the light transmission depending on the applied DC voltage. By applying a low voltage, a bluish color is achieved. When electrical charges are applied to a microscopically thin coating (for example, tungsten oxide, polyaniline), it becomes optically active and changes color. If the applied voltage is removed or the polarity of the voltage is changed, the electrochromic material becomes transparent again and the cell becomes transparent.

In addition, rearview mirror assemblies are often equipped with visual indicators to increase traffic safety. From the prior art, for example, from EP 2 463 152 A1 optical displays in an exterior mirror assembly are known. These visual displays serve primarily as warning displays and are used as indicators for turn signal functions and for different assistance systems for warning and informing the driver. A common method is to place the optical displays behind the glass assembly of the exterior mirror. From the above-mentioned European patent application is a Example known, wherein a visual display is glued as a module with a display housing and a housing cover closed on the back of the mirror glass. The warning is usually carried out by an illuminated symbol, for example in the form of a triangle. The representation of the symbol thereby by backlighting a mask, which is generated by removing the non-transparent reflector in the desired contour, for example, the triangular shape.

DE 699326252 T2 and DE 60023821 T2 each disclose a rear-view mirror arrangement for a motor vehicle which has a mirror assembly whose reflectance is changed by means of an optically active layer. Optical display modules are arranged behind the mirror assembly. The reflective coating of the rearview mirror assembly also has a recess in the optical region.

The problem with using such an optical display in a rearview mirror arrangement with an optical cell is that the optically active liquid used in the optical cell is not 100% transparent and therefore partially absorbs the light of the optical display. To compensate for this, a brighter light source is required.

The object of the present invention is therefore to further develop an automatically dimming rearview mirror arrangement for a motor vehicle having an optical cell and an optical display such that the optical cell of the rearview mirror arrangement has an improved transmission in the region of the optical display. This object is achieved by a rearview mirror assembly for motor vehicles, comprising a mirror base and a mirror head having at least one housing in which a recess for a mirror assembly is formed, wherein the reflectance of the mirror assembly is made changeable by a control device, and wherein the mirror assembly a front glass plate and an optical cell having optically active layer, and wherein an optical display module is disposed behind the mirror assembly in the interior of the mirror head, so that the light of the optical display module passes through the mirror assembly, and wherein the reflective coating in the region optical display module has a transparent recess, and the optically active layer is recessed in the region of the optical display module and this area contains an optically transparent adhesive.

By means of this rear-view mirror arrangement, in which the optical cell is designed with a transparent adhesive in the region of the optical display, the transmission can be in this range be significantly improved, which cheaper lamps can be used.

As optically active layer, all substances are combined that change their optical properties by applying an electric field. As a known example, the optically active layer is a liquid crystal layer or electrochromic layer.

It is advantageous that the optically transparent adhesive is applied flat in the recess on a foil which delimits the optical cell. By this arrangement, the displayed symbol is achieved by patterning the reflective layer of the mirror assembly, but no elaborate application of the optically transparent adhesive is required.

Again, it may be advantageous that the optically transparent adhesive is applied in the form of the symbol to be displayed in the recess on a foil bounding the optical cell, and thus does not block too much space of the optically active layer. Advantageously, the optically transparent adhesive serves as a spacer to a second, the optical cell delimiting foil, since it is applied in a defined thickness.

A particularly favorable solution is when the optical adhesive is imprintable.

Description of the invention.

Preferred embodiments of the rearview mirror assembly for a motor vehicle will now be described by way of example, with reference being made to the accompanying drawings by way of illustrative example.

Show it:

1 is a schematic view of a rearview mirror assembly as an exterior mirror assembly,

FIG. 2 shows a detail of a cross section of a mirror arrangement; FIG. and FIG. 3 shows an exploded view of the mirror assembly, with carrier plate and optical display module. FIG. 1 shows in a view a rearview mirror arrangement designed as a vehicle outside mirror 1, which comprises a mirror base 2 and a mirror head 3. The vehicle exterior mirror 1 is fastened in a known manner to the driver or passenger outside of the motor vehicle. The mirror head 3 is arranged adjustable or hinged on the mirror 2 and has a housing 4 made of a thermoplastic material. The housing 4 is half-shell-shaped and has a receiving space, which has a receiving opening towards the front. In the receiving space, a mirror assembly 5 is used, which is usually mounted on an arranged in the receiving space of the mirror housing 4 adjustable support plate 16. As can be seen from the figure, the mirror assembly 5 has a symbol 6a, which serves as a warning indicator for the driver. The symbol 6a must be recognizable and is backlit by means of an optical display module arranged behind the mirror assembly. In addition, at least one light sensor, with which the light intensity of the surroundings from the direction of the following traffic is detected, can be built into the housing 4 of the exterior rearview mirror 1. Furthermore, the light intensity of the apron of the motor vehicle is detected. Depending on the measured signals, activation and darkening of the mirror assembly 5 is then effected. However, the sensors can also be mounted as usual in the vehicle itself at the moment and connected to the vehicle exterior mirror directly or indirectly via control signals only via the signal path. The rearview mirror arrangement 1 according to the invention is described below with reference to FIG. 2, which is equipped with an automatic dimming function and is designed with an optical display in the mirror assembly 5. On the representation and detailed description of the light intensity detecting sensors, the control and evaluation of the optical cell and the optical display is omitted. This is known to the person skilled in the art.

In order to change the degree of reflection, the mirror assembly 5 according to the invention comprises, in the example shown, an optical cell designed as a liquid crystal cell 7. The liquid crystal cell 7 has a liquid crystal layer 10, which is arranged for the electrical control between two transparent electrically conductive layers 8, 9. The conductive layers are connected to carrier films or carrier material. The sealing of the liquid-crystal layer 10 between the electrically conductive layers 8, 9 takes place via a narrow circumferential adhesive layer 14, which has a sealing function and a Beabstan- dungsfunktion. As can be seen from the representation of FIG. 2, behind the mirror assembly 5 the optical display module 6 is located inside the housing on the carrier plate arranged. In this region of the liquid-crystal layer 10, the liquid-crystalline coating in the form of the symbol 6a is removed or does not exist. This area 10a is filled with a transparent optical adhesive 10b. The optical adhesive can be printed, for example, before the liquid-crystalline coating of the carrier film takes place. In this technology based on liquid crystals, the effect is exploited that when an electric field is applied to the liquid crystal cell 7, the liquid crystal molecules are oriented parallel to the electric field. In the ground state, that is to say without an electric field, the liquid-crystal molecules which are provided with color pigments are aligned in the longitudinal direction, ie the direction of passage of the light. In order to obtain this alignment, additional alignment layers are provided. These alignment layers are disposed between the electrically conductive layers and the liquid crystal layer 10, but not separately shown in FIG.

The electrically conductive layers 8, 9 are formed as films. Further, a reflective layer 12 is disposed between the back (layer facing the support plate) layer 9 and the liquid crystal layer 10. The non-transparent reflective layer 12 may in this case consist of a coating on silver, aluminum or chromium base. This layer is produced, for example, by vapor deposition or sputtering or spraying. The reflective layer can also simultaneously represent one of the conductive layers. In order for the visual display to be clearly visible on the front side of the mirror assembly 5, in the area of the optical display module i. In alignment with the region 10a on which the optical adhesive is applied, a cutout 22 is removed from the reflective coating or from the possibly additional lacquer layer on the reflective coating. This recess can be made by means of a laser or by etching out in the form of the symbol 6a to be displayed. Removing the reflective layer in the symbol area also removes the alignment layer for the liquid crystal molecules. As a result, the liquid crystals would always be disordered in this area and would absorb strongly. Filling the symbol contour in the area of the recess avoids this problem.

Seen from the front V of the mirror assembly 5, is on the transparent

Layer 8 a glass layer 1 1 arranged. The glass layer 1 1 has the function of a scratch protection. In a further embodiment, the optical cell of the mirror assembly 5 can also be embodied as an electrochromic cell. In contrast to the arrangement described above, an electrochromic liquid is arranged sealed between the transparent conductive electrically controllable layers. As already described above and can be seen in Figure 3, the mirror assembly 5 is mounted on a support plate 15 in the housing 4. The optical display module 6a is arranged in a cutout or a depression of the carrier plate 16. In the illustrated embodiment according to FIG. 3, a heating layer 15 is still fixed on the rear side of the mirror assembly 5 via a circumferential adhesive edge layer. This is optional. As can also be seen, the heating layer 15 is made recessed in the region of the optical display module 6 in the form of the symbol 6a, so that the light beams emitted by the optical display module 6 can pass through the heating layer 15 unhindered. The visual display module 6 is known from the prior art and will therefore be described only briefly. It essentially comprises a module housing 17 in which a circuit board with lighting means 18 is arranged. Furthermore, a light-guiding body 19 is provided, which guides or deflects the light emitted by the light-emitting means 18 in such a way that the light radiates through the transparent region in the form of the symbol through the mirror assembly 5. The lamps are LEDs or other known bulbs used.

Claims

Claims:

1 . Rearview mirror arrangement (1) for motor vehicles, having a mirror base and a mirror head, which has at least one housing in which a recess for a mirror assembly (5) is formed, wherein the reflectance of the mirror assembly (5) is made variable by a control device, and wherein the mirror assembly (5) has a glass plate (11) arranged on the front side and an optical cell (7) having an optically active layer (10), and an optical display module (6) behind the mirror assembly (5) inside of the mirror head is arranged, so that the light of the optical display module (6) passes through the mirror assembly (5), and wherein the reflective coating (12) in the region of the optical display module (6) has a translucent recess, characterized in that the optically active layer (7) is recessed in the region of the optical display module (6) and this region is an optically transparent adhesive he contains.

Second rearview mirror assembly (1) for motor vehicles according to claim 1, characterized in that the optically active layer is a liquid crystal layer or electrochromic layer.

3. rearview mirror assembly (1) for motor vehicles according to claim 1 or 2, characterized in that the optically transparent adhesive is applied flat in the recess (22) on a the optical cell limiting film (9,10).

4. rearview mirror assembly (1) for motor vehicles according to claim 1 or 2, characterized in that the optically transparent adhesive in the form of the symbol to be displayed (6a) in the recess (22) on a the optical cell limiting film (9,10) is applied ,

5. Rearview mirror arrangement (1) for motor vehicles according to one of the preceding claims, characterized in that the optically transparent adhesive is applied as a spacer to a second, the optical cell delimiting film (9,10) in a defined thickness.

6. rearview mirror assembly (1) for motor vehicles according to one of the preceding claims, characterized in that the optical adhesive can be imprinted.