DE19631409A1 - Variable transmission assembly preferably of glass - Google Patents

Abstract

An assembly, having two transparent (preferably glass) support layers, a reflective coating and a variable transmission layer system, also includes a semi-transparent mirror layer. Preferably, the variable transmission layer system is an electrochromatic or liquid crystal system and the semi-transparent mirror layer is an interference mirror layer, a semi-transparent chromium or silver mirror layer provided on the fourth or third surface, an additional mirror layer optionally being provided on the first and/or second surface.

Description

The present invention describes a mirrored glass assembly with variable transmission or reflection, which especially for use in automotive rearview systems, especially in combination with displays and sensors, and at Glazing of motor vehicles and buildings is advantageous.

There are known automatically dimmable rear view mirror systems to reduce the glare from headlights of subsequent motor vehicles. These generally have two light sensors and recognize the glare condition from the difference in the light intensity falling on the sensor facing forward ( 21 ) and rearward ( 20 ). A reduction in the degree of reflection from the mirror glass ( 29 ) is then triggered via an electrical field.

To change the reflectance, polarization systems based on liquid crystal (LC) and absorption systems based on electrochromatic (EC, e.g. tungsten oxide gel) are known. In Fig. 1, the currently most common EC system is shown. There is an EC between two transparent carrier materials, preferably glasses, coated with a transparent, electrically conductive indium tin layer (IT) or indium tin oxide layer (ITO) ( 2 , 4 ), ( 1 , 5 ) Layer ( 3 ). Fig. 2 shows an optimized system. To reduce ghosting, the mirroring ( 9 ) is not on the so-called fourth surface, i.e. behind the glass ( 5 ), but on the so-called third surface and thus between the glass and the EC layer, in this example between the IT layer ( 4 ) and the glass ( 5 ). Fig. 3 shows an LC system with the glasses ( 1 ) and ( 5 ), the IT layers ( 2 ) and ( 4 ), the LC layer ( 7 ) and the non-transparent mirror coating ( 9 ). In contrast to the EC systems, in which absorption takes place in the EC layer when controlled by an electric field, the use of linearly polarizing filter layers ( 6 ) and ( 8 ) is still necessary for the LC systems, since the LC medium can only rotate the direction of polarization between horizontal and vertical. A transmission reduction and thus darkening only occurs if the direction of polarization of the light after the LC layer is not identical to that of the linear polarization filter connected downstream. According to the prior art, the mirroring ( 9 ) consists of a non-transparent coating based on silver or chrome. EC systems thus achieve a degree of reflection in the light or dark state of around 70% or 8%. Due to the linear polarization filters, which have a maximum transmission of 50% due to their physical nature, LC systems can only achieve a maximum reflectance of around 45%. Fig. 4 shows an LC system in which, in contrast to the system of Fig. 3, the reflective layer ( 9 ) for reducing ghosting in front of the glass ( 5 ) is arranged on the so-called third surface.

Vehicle rear view mirrors are suitable for integrating displays due to their optically favorable installation position. In such systems, for example, the time or the cardinal direction (compass function) is displayed. For this purpose, as shown in FIG 5 and FIG. 13 is. Shown recessed, the mirror coating (9) in the region (26) of the display. The display itself is usually an independent liquid crystal display module ( 10 ), which is attached behind the glass ( 5 ).

A disadvantage of systems according to the prior art is that the savings required for a sensor or a display ( 26 , 27 ) the mirroring in the display or sensor area of the mirror can no longer meet its original task of reflection. The reflection image visible in the mirror is interrupted by the surface ( 26 , 27 ) of the display or sensor. Fig. 13.

The system according to the invention now enables, as shown in Fig. 14, to mount the display so that the display in the switched-off state does not affect the reflective property of the automatically darkening rear view system at any point and enables a high-contrast display both during the day and at night. In the case of sensors arranged behind the glass module ( 25 ) according to the invention, such as the rear light sensor ( 20 ), as shown in FIG. 14, the same positive effect of being invisible from the outside is achieved.

Ideally, according to the invention, the reflection layer ( 9 ) is designed as a semi-transparent reflection layer ( 11 , 13 ). It proves to be particularly advantageous: the design as interference mirroring ( 11 ) with non-linear transmission and non-linear reflection. As shown in FIG. 6, the reflection is considerably higher in the lower wavelength range and significantly lower than the transmission in the upper wavelength range. Such mirroring is built up, for example, by a thin layer system based on titanium oxides, silicon oxides, and / or iron oxides. The desired reflection or transmission behavior and also the color impression of the reflection layer can now be set by varying the layer material and the layer thickness or number of layers. If, for example, the display is designed as a red LED display, high transmission can be achieved in the wavelength range of 630 nm and high reflection in the wavelength range below 600 nm. It is possible to transmit the spectrum for the display to achieve over 50% with a total reflection according to DIN under standard light A of also over 50%. In order to prevent undesired transmissions, as in FIG. 7, the system in the area not used by the display is to be provided on the back with a further non-transparent layer ( 12 ), such as preferably black lacquer or enamel.

If displays with a high light intensity are available and / or a lower overall reflectance according to DIN is sufficient, the semi-transparent reflective layer can also be realized by a thin mirroring, for example based on chrome or silver. Such a mirror coating ( 13 ) generally has a linear transmission and reflection characteristic, as shown in FIG. 8. The transmission waves are clearly below the reflection regardless of their length. A basic structure as shown in FIG. 7 is also possible here.

In order not to be able to recognize an LED display in the switched-off state behind a semi-transparent mirroring ( 11 ) or ( 13 ), it is advantageous to arrange an additional filter layer ( 15 ) with a non-linear transmission characteristic between the mirroring and the display ( 14 ) . Fig. 9 shows some such color selective transmission curves. Such filters ( 15 ) enable a narrower transmission bandwidth than is possible with interference mirroring ( 11 ). But they also enable optimization of the overall system in the case of semi-transparent mirroring ( 13 ) with a linear transmission curve. An optional additional circular polarizing filter layer ( 16 ) between the glass ( 5 ) and the display ( 14 ) prevents unwanted reflections on the display due to light shining on the system from the outside and thus improves the overall optical impression of the system by switching the display off Condition can not be seen from the outside. Ideally, these two filters ( 15 ) and ( 16 ) are combined in a circular polarizing filter ( 17 ) with a nonlinear transmission characteristic.

If the display should only be readable from a certain angle, for example to provide only the driver with information that cannot be seen from the front passenger seat, a light guide film ( 18 ) can also be placed between the glass ( 5 ) and the display ( 10 ). to be ordered. This ge in Fig. 10 showed light guide film has, for example, thin absorbent lamellae ( 19 ), which are in the desired viewing angle.

If, as is known from LC display technology, the transparen th electrically conductive layers ( 2 ) and ( 4 ) are carried out in segments and contacted segment by segment, a display is also possible with a reflective coating ( 9 ) according to the prior art. This is done in daytime operation by darkening or in dimmer operation by brightening the relevant segments. This results in a dark display on a light background during the day and an inverse light display on a dark background at night. The disadvantage here is the low contrast, especially at night. Here, the bright display requires additional lighting from ambient light, such as from the following vehicles. Advantageously, a contrast increase can be achieved according to the invention with a semi-transparent mirroring ( 11 ) or ( 13 ) and a backlighting of the display. This makes it easy to read the active display during day and night operation and the display is hidden from the outside when switched off and does not reduce the overall reflective surface of the vehicle rear view system.

With the system according to the invention, it is now possible to build auto-darkening vehicle rear view systems in which a display is integrated behind the mirror glass so that the display is not recognizable when switched off and does not reduce or interfere with the reflective surface of the system. Such displays can include, for example, taximeter information such as fare, tariff, taxi number etc. in the vehicle interior mirror or distance indicators for parking assistance systems in the interior and / or exterior mirror or warnings from so-called blind spot detection systems in the exterior mirror or also display the direction of travel. Advantageously, such display systems can also be designed as a multifunction display with a BUS interface. Of course, the inventive system also allows, as shown in FIG. 11 and FIG. 12, assembly invisible from the outside of the mounting necessary for the control of the EC and LC-system rear light sensor (20) behind the glass (25). In Fig. 12 is also the forward through an opening in the housing ( 22 ) of the rearview system ambient light sensor ( 21 ) and the control electronics ( 23 ) for controlling the transmission of the glass assembly according to the invention ( 25 ) and the electronics ( 24 ) for the Display ( 10 ) shown. A dimming of the display ( 10 ) can be controlled with information about the ambient brightness or the state of reflection. Components of the mirror can be supplied with energy via a photo element or a solar cell ( 28 ).

Another application of the glass assembly according to the invention represent shading systems. The semi transparent reflection layer are carried out so that the Reflection high in the infrared range and in the visible range Light is low. Through the integrated, in its transmis sion variable layer system can then the transmission of the visible light can be controlled. The glass according to the invention The module can be used in office glazing or for example Motor vehicle sunroofs are used advantageously.

Claims (29)

1. An assembly with at least two transparent carrier layers, preferably glass, at least one reflection coating and a layer system whose transmission can be changed, characterized in that the assembly or glass assembly has at least one semi-transparent mirror coating. 2. System according to claim 1, characterized records that the layer is variable in its transmission system consists of an electrochromatic system. 3. System according to the invention according to claim 1, characterized records that the layer is variable in its transmission system consists of a liquid crystal system. 4. System according to the invention according to at least one of the claims 1 to 3, characterized in that the semi-transparent Mirroring is located on the fourth surface. 5. System according to the invention according to at least one of the claims 1 to 3, characterized in that the semi-transparent Mirroring is located on the third surface. 6. System according to the invention according to at least one of the claims 1 to 5, characterized in that on the first and / or additional mirroring applied to the second surface is. 7. System according to the invention according to at least one of the claims 1 to 6, characterized in that the semi-transparent Ver Mirroring is designed as interference mirroring.   8. System according to the invention according to at least one of the claims 1 to 6, characterized in that the semi-transparent Ver Mirroring implemented as semi-transparent chrome mirroring is. 9. System according to the invention according to at least one of the claims 1 to 6, characterized in that the semi-transparent Ver mirroring executed as semi-transparent silver mirroring is. 10. System according to the invention according to at least one of the Claims 1 to 9, characterized in that the semi transparent mirroring a nonlinear transmission and Shows the reflection characteristic. 11. System according to the invention according to at least one of the Claims 1 to 9, characterized in that the semi transparent mirroring in the area of visible light a largely linear transmission and Has reflection characteristic. 12. System according to the invention according to at least one of the Claims 1 to 11, characterized in that behind the semi-transparent mirroring a light-absorbing mask is applied. 13. The system according to claim 12, characterized records that the mask has cutouts for at least one display and / or at least one sensor and / or at least one photo element. 14. System according to the invention according to at least one of the Claims 12 to 13, characterized in that the mask dark lacquer and / or enamel.   15. System according to the invention according to at least one of the Claims 1 to 14, characterized in that behind the semi-transparent mirroring a color selective filter layer arranged with a non-linear transmission characteristic is. 16. System according to the invention according to at least one of the Claims 1 to 14, characterized in that behind the semi-transparent mirroring a circular polarizing Filter layer is arranged. 17. System according to the invention according to at least one of the Claims 1 to 14, characterized in that behind the semi-transparent mirroring a circular polarizing and color-selective filter layer is arranged. 18. System according to the invention according to at least one of the Claims 1 to 17, characterized in that behind the semitransparent mirroring a layer, for example in Shape of a light guide film with thin absorbent lamellas, is applied, which a viewing angle selectivity at a arranged behind the display. 19. Use of the at least one of claims 1 to 18 characterized system according to the invention, characterized records that the two electrically conductive layers of in its transmission controllable EC or LC layer system are segmented so that by a suitable interconnection of the Segments a display with light letters on dark Background or dark writing on a light background is possible. 20. Use of the at least one of claims 1 to 19 characterized system according to the invention, characterized thereby records that behind the semi-transparent reflective layer at least one light source for backlighting or lighting device is arranged.   21. Use of the at least one of claims 1 to 20 characterized system according to the invention, characterized records that behind the semi-transparent reflective layer at least one LED display is arranged. 22. Use of the at least one of claims 1 to 20 characterized system according to the invention, characterized records that behind the semi-transparent reflective layer at least one liquid crystal display is arranged. 23. Use of the at least one of claims 1 to 22 characterized system according to the invention, characterized records that the system is in a vehicle rearview mirror is integrated and the display according to at least one of the An say 19 to 22 taximeter information. 24. Use of the at least one of claims 1 to 22 characterized system according to the invention, characterized records that the system is in a vehicle rearview mirror is integrated and the display according to at least one of the Claims 19 to 22 park assistance information such as wise distance information and / or direction indicators and / or warnings such as messages from a blind Spot detection systems can display. 25. Use of the at least one of claims 1 to 22 characterized system according to the invention, characterized records that the system is in a vehicle rearview mirror is integrated and the display according to at least one of the Claims 19 to 22 as a multifunction display with a BUS cut place is executed.   26. Use of the at least one of claims 1 to 18 characterized system according to the invention, characterized records that the need for transmission control of the system rear light sensor behind the system in one Execution in particular according to at least one of claims 7 to 18 is arranged. 27. Use of the at least one of claims 1 to 18 characterized system according to the invention, characterized records that at least one photoelement behind the system in an execution in particular according to at least one of the Claims 7 to 18 is arranged. 28. Use of the at least one of claims 19 to 25 characterized system according to the invention, characterized records that the luminosity of the at least one display and / or the backlight (s) of at least one display in Dependence of the ambient brightness and / or the darkening state of the layer that can be changed in its transmission and / or the state of the driving lights is dimmable. 29. Use of the at least one of claims 1 to 18 characterized system according to the invention, characterized records that the system in the building glazing or Motor vehicle glazing is used and at least one has high reflection in the infrared range.