DE7801893U1 - Liquid crystal mirrors, in particular for use as a rearview mirror in a vehicle - Google Patents

Description

Liquid ski mirror, in particular for use as a rearview mirror in a vehicle.

The invention relates to rearview mirrors for vehicles.

It is a well known unpleasant fact that the driver of a vehicle, in particular a motor vehicle, from the light beams of the headlights of those following him Vehicles is dazzled when they are reflected from the rearview mirror of the vehicle.

To avoid this disadvantage is the use of rearview mirrors known, their reflectivity between a high reflectance and a weaker reflectance is changeable. This can be achieved, for example, that the rearview mirror with two one behind the other reflective surfaces is equipped that have a weak or strong degree of reflection and with a are arranged a certain distance from each other.

Such a rearview mirror can thus be used during the day in a high reflectivity state in order to protect the vehicle driver to offer a good view of the reflected objects, while at night, however, in the state of low reflectivity is used to avoid dazzling the driver.

Mirrors are also known to have the properties of nematic, shear liquid crystals that normally

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are translucent, but if they are sufficiently large, beyond a predetermined threshold from the exner When exposed to an electrical voltage of the order of 10-15 V, a state of turbulence is created through which light is damped to an increasing extent with the size of the applied electric field.

After switching off the electric field, the liquid crystal returns back to its transparent state. So you get a high or low level with such mirrors Degree of reflection depending on whether in the liquid crystal one below or above the mentioned threshold lying electrical voltage is effective.

A disadvantage of all of these systems, however, is that the image of the reflected objects is clear to the driver of the vehicle appears heavily clouded if the mirror has a low degree of reflection work.

The invention is based on the object of a liquid crystal mirror to create, which is particularly suitable for use as a rearview mirror of a vehicle that has the Avoids dazzling the vehicle driver by the headlights of the following vehicles and the vehicle driver one allows a sufficiently clear view of the objects reflected by the mirror.

Starting from a liquid crystal mirror with a housing in which a plurality of optical elements are arranged is, which consists essentially of a front transparent electrically insulating on its back with a thin transparent layer of electrically conductive material covered plate, from a rear to the front Plate just opposite and on its surface facing the front plate mix a layer of reflective electrically conductive material covered electrically insulating plate and an between

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The chamber lying between the two plates consists of a liquid crystal layer in nematic form and bounded laterally by a strip of insulating material and is sealed along the circumference of the facing surfaces of the two plates between them is arranged, the two conductive layers for generating an electric field in the liquid »Metal layer can be connected to a voltage source, this object is achieved in that the rear surface the front plate has a plurality of fields that are not covered by the electrically conductive material and which are arranged in the form of a grid with substantially orthogonal grid lines.

According to a further development of the invention, the fields have a square shape.

The invention is explained in more detail below with reference to the exemplary embodiment shown in the drawings:

FIG. 1 shows a front view of a mirror according to FIG Invention,

Fig. 2 shows a transverse section along the line II-II of Fig. 1,

3 shows a rear view of the front plate of the optical system;

Fig. 4 shows a cross section on an enlarged scale along the line IV-IV of Fig. 3,

Fig. 5 shows the electrical circuit for regulating the voltage between the electrically conductive layers of the mirror.

The mirror shown in Fig. 1 to 4 has a housing 2 which contains the optical elements of the mirror. These optical elements are clamped, for example, between a front and a rear housing part. That Housing 2 is via a ball joint 4 with the end of a

Support arm 6 connected, the other end of which opens into a plate 8, the holes 10 for attaching the mirror owns the body of a vehicle.

The optical elements of the mirror are held in a seat 3 of the housing 2. They consist of a front one Plate 14 made of transparent material, for example made of glass or plastic, the back of which is covered by a layer 18 is covered from electrically conductive material; this layer 18 is extremely thin and therefore transparent. Her Thickness is on the order of 100 to 1000 angstroms depending on the type of material.

This conductive layer is discontinuous because the back of the plate 14 is a multitude of uncovered small ones Fields 30. These small fields 30 preferably have a substantially square shape with a Edge length of 0.3 to 1 mm each, with the centers of the fields about 1.5 to 3 mm apart. The fields 30 are arranged in a grid-like distribution along grid lines which are essentially orthogonal to one another get lost.

Behind the plate 14 is e ⁱ ne transparent plate 20, which the plate is covered of conductive material 14 facing front side with a continuous layer 24th Their back is metallized in the usual way with mirrors, so that good reflective properties are obtained. As with normal mirrors, the metallization layer is covered with a protective coating.

The above-mentioned conductive layers can be in any known manner, for example by deposition in the Be applied vacuum. Various materials such as chromium, tin or indium oxide, or indium oxide doped with tin oxide or tin can be used.

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The opposing but slightly offset in height plates 14 and 20 are by a Strips of insulating material 26 spaced along the edge of their facing surfaces and which has such a strength that there is a distance of several 1/100 to about 1/10 mm, preferably from 1/100 to 3/100 mm, is guaranteed. In this way, the two plates 14 and 20 delimit and the strip 26 has a chamber 23.

The chamber 28 is filled with a layer of a substance which, at least at medium operating temperatures, has the properties of a nematic liquid crystal. It can be, for example, N- (p-methoxy-benzilidene) -p-n-butylaniline from Kodak or the product Nematic mixture dynamic scattering II (Eastman 11 880) of the same Act company.

The overall complex of the optical elements described is covered on its side surface with a layer 40 of hardening Material, for example the Firiua E-POX-E product Woodhill covered.

A photocell 50 attached to the front of the housing 2 of the mirror is connected via a conductor 50a to a electrical circuit 52 connected, which is located in a recess 51 of the mirror provided behind the optical elements is located, and is fed from the electrical system of the vehicle via lines 54 and 56, the through holes made in the support arm 6 and the body 52.

Two conductors 32 and 34 connect the outputs of the circuit 52 with layers 18 and 24, respectively.

The connection between these layers and the conductors are made by a conductive paint, for example

ien Silver Print paint from 0. C. Electronics (Rock-Ford, III, USA) formed, the connection points with insulating varnish to be covered.

to FIG. 5, it is seen that the photocell is verbunien 50 with the Sxngang 102 of an amplifier 104 of the circuit 52, whose second input is 106 angeschlossei to ground.

The output 108 of the amplifier 104 is connected to the base of a transistor 110, the emitter of which is connected via a resistor 112 is connected to the input 114 of a trigger circuit 116, while the collector of transistor 110 ax is connected to the conductor 118, on which the supply voltage is applied. Between the conductor 118 and ground is a voltage divider consisting of the resistors 120 and 122 arranged. The input 123 of the trigger 116 is connected to a variable resistor 126 wiper 124 of the resistor 122 of said voltage divider in connection. The output of the trigger 11i * ird is fed to a first input 130 of an astable multivibrab 132, the second input 134 of which is connected to the connection point between the resistors 136 and 138 one lus these two resistors and one in series with them switched capacitor 140 formed voltage part is included. The supply of the astable multivibrator 132 takes place via conductor 142. Between its exit and ground is a voltage divider 142 connected "?", des 3en rotor is connected to the base of a transistor 144 serving as an amplifier. The emitter of this transistor is connected to ground, its collector is with its winding end of the primary winding of a transformer laboratory 146 in connection, the other winding end of which is connected to iem feeder 118. The secondary winding This transformer is connected to conductors 32 and 34 which lead to conductive layers 18 and 24.

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The circuit shown in Fig. 5 operates as follows:

The signal fed to the input 102 of the amplifier 104 the photocell 50 is converted into a voltage signal and amplified. At point B there is thus a tension, which is a function of the intensity of the incident on the photocell Is light.

The signal of point B is fed to the comparator circuit. This comparator circuit has a hysteresis. This serves to avoid the generation of continuous vibrations when the intensity of the on the When the light hits the photocell, it oscillates with a small amplitude around the wave value.

The threshold value is set by the potentiometer 22, while the width of the hysteresis is set by the potentiometer 22 stand 126 is adjustable.

When the voltage at the input 114 of the comparator 116 den Threshold plus half the hysteresis voltage ups; exceeds, the comparator tilts and activates the following stages. When the voltage at input 114 drops and falls below the threshold value minus half the hysteresis voltage, the comparator toggles in the opposite direction Direction. The output signal of the comparator 116 reaches the astable multivibrator 132, which works as an oscillator and its oscillation frequency is determined by the value of resistors 136 and 138 and capacitor 140 is. The AC output voltage of the astable multivibrator 132, which has a low level value, comes EU the transistor 144, is amplified in this and that Transformer 146 is supplied, which feeds the conductive layers 18 and 24 via the conductors 32 and 34.

The primary voltage of the transformer 146 can be determined by the

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* ι Ι

Potentiometer 142 can be regulated.

The function of the mirror is described below:

During the day, or even under conditions in which there is no risk of glare, the lines from the sv sorgungsquelle with which they are connected, isolated so that there is inside the liquid crystal layer an electric field, and this therefore has its greatest transparency. The images of the objects behind the vehicle are reflected with the greatest possible intensity and are therefore clearly visible to the driver of the vehicle.

If, on the other hand, the mirror causes the driver to be dazzled as this happens, for example, at night when other vehicles are switched on behind the vehicle Move the headlights to a corresponding one Limit value calibrated photocell 50 the conductor and 34 automatically with the supply source, so that the Liquid crystal layer is exposed to an electrical voltage which is above the threshold value. Consequently the layer attenuates the reflected light. However, this damping does not take place over the entire surface of the mirror takes place, since the electric field is only between the layer 24 and the parts of the rear side of the plate 14 acts, which are covered by the layer 18 of conductive material, so that only in these zones, the reflected light is effectively weakened. In the area of the small fields of the surface of the plate 14 that are not conductive Material are covered, the electric field does not work, so that there is no weakening of the light.

The driver of the vehicle therefore sees the images of the objects behind the vehicle as if through a grille of more or less bright cells. this has

the advantage that the glare is reduced considerably, but the clarity of the reflected images is not essential suffers.

The square shape of the small panels 30 has proved to be extremely effective in comparison to other shapes _f the one hand to achieve a reduction in glare and on the other hand a clear reproduction of the reflected images.

Claims (6)

- 10 protection claims 1. Liquid crystal mirror, especially for use as a rearview mirror in a vehicle _> with a housing in which a plurality of optical elements are arranged, which essentially consist of a front transparent electrically insulating cover on their back with a thin transparent layer of electrically conductive material Plate, consisting of a rear plate just opposite the front plate and on its surface facing the front plate covered with a layer of reflective electrically conductive material electrically insulating plate as well as a chamber lying between the two plates, which contains a liquid crystal layer in nematic form and which is laterally bounded and sealed by a strip of insulating material, which is arranged along the circumferential line of the facing surfaces of the two plates between these, the two conductive layers for generating an electrical cal field in the liquid crystal layer can be connected to a voltage source, characterized in that the rear surface of the front plate (14) has a plurality of fields (30) which are not covered by the electrically conductive material (18) and which are in the form of a Grid (Fig. 3) are arranged with essentially orthogonal grid lines. 2. Mirror according to claim 1, characterized in that the fields have a square shape. J. Mirror according to Claim 2, characterized in that that the substantially square fields (30) have a side length of 0.3 to 1.0 mm, while their centers are apart from each other by 1.5 to 3.0 mm. 4. Mirror according to one of the preceding claims characterized in that the housing (2) has a cavity (51) located behind the rear plate (20) owns, in which an electrical control circuit for regulating the between the electrically conductive Layers, 18, 24) effective tension is arranged. 5. Mirror according to one of claims 1 to 4, characterized in that on the front outer surface of the Housing (2) a photocell (50) is arranged. 6. Mirror according to one of the preceding claims, characterized in that the opposite Plates (14, 20) are offset in height from one another and that the conductors for feeding the two electrically conductive layers are connected to these in the area of their edge zones.