DE10100672A1 - Heated LCD display - Google Patents

Abstract

A heatable LCD display is shown, in which heating is implemented by means of an extended sheet resistance (8) below the active area (9) of the display. To heat this layer (8) is applied to an electrical voltage, which, however, must be controllable so that the liquid crystal display is not destroyed due to overheating. For this purpose, a temperature sensor (12) is arranged above the surface resistance (8), but next to the active area (9) of the liquid crystal display. The active area (9) and the temperature sensor (12) are thus supplied with thermal energy in the same way, so that the temperature determined by means of the temperature sensor (12) corresponds to that of the active area (9) of the liquid crystal layer.

Description

The invention relates to a heatable LCD display, in particular in a motor vehicle, with at least two arranged one above the other Substrates, an active area for information display, with on surface resistance is applied to one side of one of the substrates, a controllable at the opposite edges via busbars re electrical voltage can be applied, and with a temperature sensor Determine the display temperature in the active area.

An LCD display consists of two substrates, usually glass sheets ben, between which an electrically controllable liquid crystal layer is ordered. The structure of the layer allows segment-wise control to the layer so that such a display for displaying symbols, Numbers and letters is suitable.

The liquid crystal layer only works at a certain temperature area optimal. If e.g. B. lower temperatures are present optical changes to the layer that ultimately cause the display Applying a voltage only extremely delayed. In all areas of application Chen, at which such non-optimal temperatures occur and despite who need a quickly adjustable, dynamic display are there forth displays used that at least the active area, d. H. the control heatable area of the liquid crystal layer.  

Since this layer is sensitive to temperature, i.e. if the temperature is too high is destroyed, the heating is controlled, which is why a temperature is shown on the display temperature sensor is installed. With the previously used heated displays the heater was only located under the active area of the LCD and the temperature sensor so distant that the heat conduction to active area was better than that to the sensor. The measured on the sensor Its temperature therefore did not correspond to the temperature of the liquid crystal layer, so that for the regulation of heating complicated compensation methods that ultimately resulted in the LCD could not be operated in the optimal temperature range.

Furthermore, there are heaters consisting of a sheet resistance known, this resistance as a thin layer on one of the glass panes ben the LCD display is applied. Here, too, the limit was limited stretch the area on the active area of the display so that from the above-mentioned reasons the display temperature is not optimal could be.

The invention is therefore based on the problem of a heatable LCD display create, in which a simple heating control is realized can, so that the display even at a low ambient temperature temperature can be quickly brought to an optimal working temperature.

To this end, the invention proposes that the sheet resistance laterally the active area goes out and the temperature sensor next to the acti Ven area above and in contact with the surface resistance is arranged.

As a result, the temperature sensor works in the same way as the active area of the liquid crystal layer is heated and thus that of Sensor detected temperature always corresponds to that of the liquid crystal layer. By means of the temperature sensor, the heating is in an inventive LCD display not only controllable, so z. B. when reaching a fixed temperature can be switched off, but by the exact, timely tem temperature detection can also be sensibly controlled. In this way, e.g. Belly Influences of the ambient temperature are also taken into account.  

The easiest way to mount the temperature sensor is when the top Half of its location, a space next to one of the substrates of the LCD Ad is located.

In order to realize this free space, it is advantageous that with the area wi the substrate provided in the stack belongs to the LCD display arranged substrates that it laterally over at least one other Protrudes substrate of the LCD display, so that the temperature sensor upper can be attached half of the protruding part of the substrate.

In the simplest case, the temperature sensor can be connected directly to the surface resistance can be brought into contact. In this way, the Determine temperature very precisely.

On the other hand, this is not due to the design of the LCD display always possible so that the temperature sensor is away from the surface stand must be attached. In this case, however, it is advantageous ensures that the temperature sensor is continuously perpendicular to the Surface resistance heat conduction path with the surface resistance is in contact.

This not only results in a particularly space-saving design, but has in usually also results in a heat conduction path, its thermal conductivity that of the contact between the sheet resistance and the active loading rich corresponds to the liquid crystal layer.

As a rule, this heat conduction path is formed by a substrate. Entwe this is the substrate on which the sheet resistance is applied, the temperature sensor on the opposite side surface of the Is arranged substrate, or it is one or more more Substrates that rest on the sheet resistance.

As already explained above, the temperature sensor should advantageously be in egg free space. This free space can preferably also can be used to create a driver for the liquid crystal layer in the LCD  Arrange ad. This driver is advantageous via a flexible ladder plate powered. It is therefore still proposed to be preferred also assign the temperature sensor to the control with this conductor connection.

Temperature sensors that contain an NTC resistor have chosen this area of application has proven to be particularly suitable.

An electrically conductive transparent is preferred as the surface resistance Layer applied to one of the substrates of the LCD display. A special The most suitable material for this layer is indium tin oxide.

In the following, the invention is to be illustrated in a single figure based on of an embodiment will be explained in more detail.

The picture shows the edge area of a DSTN display (Double Super Twisted Nematic display). In principle, these are two LCDs which are arranged one above the other, each LCD consisting of two substrates designed as glass panes, between which the liquid crystal layer, not shown here, is arranged. The upper LCD is referred to as the active LCD 1 and the lower as a passive LCD 2 , the actual display being carried out with the active LCD 1 and color compensation (reduction or elimination of color distortions) with the passive LCD 2 .

The DSTN display thus has four glass panes 3 , 4 , 5 , 6 , the two upper glass panes 3 , 4 belonging to the active LCD 1 and the two lower glass panes 5 , 6 belonging to the passive LCD 2 . The two LCDs 1 , 2 are connected to one another by means of an adhesive 16 .

On the underside of the upper glass pane 5 of the passive LCD 2 , an ITO heating layer 8 is applied continuously. ITO stands for indium tin oxide. Another heating layer 15 is applied to the top of the lower glass pane 6 . However, the provision of only one of the heating layers 8 , 15 is sufficient for the function of the heating.

Each of these layers 8 , 15 is on two busbars, which are not shown here, ver at opposite edges with voltage. The current flowing across the layer heats the layer and heats up the display.

The active surface 9 of the active LCD 1 is limited by the illustrated longitudinal edge 7 of the upper glass pane 3 of the active LCD 1 . At least the controllable area of the liquid crystal layer is only between the upper glass pane 3 and the lower glass pane 4 of the active LCD 1 .

However, the ITO heating layers 8 , 15 extend beyond this longitudinal edge 7 , so that not only the active area 9 is heated by these ITO heating layers 8 , but also the adjacent areas 10 .

In the present case, a temperature sensor 12 is not applied directly to one of the ITO heating layers 8 , 15 , but at a distance therefrom with the interposition of the lower glass pane 4 of the active LCD 1 , which glass pane 4 is also laterally extended beyond the longitudinal edge 7 for this purpose.

The heat flow through the lower glass pane 4 thus takes place not only in the active area of the LCD 1 , but also in the side area where the temperature sensor 12 is located.

The temperature sensor 12 can be designed as an individual component, but also as an integrated component of the driver for the liquid crystal layer. The power supply to the driver and the connection of the Temperatursen sensor 12 to the controller takes place via a flexible printed circuit board 13 , which has been brought up to the display since Lich and rests on the top of the lower glass pane 1 of the active LCD 1 .

For a secure connection of the driver, the temperature sensor 12 and parts of the flexible conductor track 13 , these components are cast in a casting compound 14 on the display.

As already mentioned in the introduction to the description, the ITO heating layer 8 does not necessarily have to be arranged on the glass pane of an LCD, rather what is particularly the case when the display consists only of an LCD, a separate glass pane belonging to the display can be provided, which only serves to support the ITO heating layer 8 . The temperature sensor 12 does not have to be arranged at the same height of the liquid crystal layer to be heated. Rather, it is crucial that the conductivity of the heat conduction path between the ITO heating layer 8 and the temperature sensor 12 roughly corresponds to that of the heat conduction path between the liquid crystal layer to be heated and the ITO heating layer 8 .

Claims (10)

1. Heated LCD display, in particular in a motor vehicle, with at least two superimposed substrates, an active loading area for information display, wherein on one side of the sub strate a sheet resistance is applied, a controllable electrical at the opposite edges via busbars Voltage can be applied, and with a temperature sensor for determining the display temperature in the active area, characterized in that the surface resistance ( 8 ) extends laterally beyond the active area ( 9 ) and the temperature sensor ( 12 ) next to the active area ( 9 ) above the surface resistance ( 8 ) and is arranged in contact with it. 2. LCD display according to claim 1, characterized in that above the attachment point for the temperature sensor ( 12 ) there is a space ne ben of one of the substrates of the LCD display. 3. LCD display according to claim 2, characterized in that the provided with the sheet resistance ( 8 ) substrate ( 5 ) protrudes laterally over a white teres substrate ( 3 ) of the LCD display and that the temperature sensor ( 12 ) above the protruding Part of the substrate ( 5 ) is attached. 4. LCD display according to one of claims 1 to 3, characterized in that the temperature sensor ( 12 ) is directly in contact with the surface resistance ( 8 ). 5. LCD display according to one of claims 1 to 3, characterized in that the temperature sensor ( 12 ) via a continuous perpendicular to the surface resistance ( 8 ) extending heat conducting path with the surface resistance ( 8 ) is in contact. 6. LCD display according to claim 5, characterized in that the temperature sensor ( 12 ) with the interposition of the surface resistance ( 8 ) carrying substrate ( 5 ) and / or a further substrate ( 4 ) of the LCD display with the surface resistance ( 8 ) is in contact. 7. LCD display according to one of the preceding claims, characterized in that the temperature sensor ( 12 ) is arranged next to a driver for the liquid crystal layer of the LCD display. 8. LCD display according to claim 7, characterized in that the temperature sensor ( 12 ) on a flexible circuit board ( 13 ) for the Stromzufüh tion is attached to the driver. 9. LCD display according to one of the preceding claims, characterized in that the temperature sensor ( 12 ) has an NTC resistor. 10. LCD display according to one of the preceding claims, characterized in that the surface resistance is formed from an electrically conductive transparent layer ( 8 ).