DE2554226A1 - Display unit with passive brightness attenuation - using mirrored fluorescent plastics plate behind fluidic crystal cell and using linearly polarised plates - Google Patents

Abstract

The diplay unit, providing a single or multi-coloured display, has means for attenuating the brightness of the display. A fluorescent plastics plate (5), which is mirrored on its rear face (6a), is positioned behind the fluidic crystal display cell (2) and has light exit windows (7) conforming with the display elements (3) of the display cell (2). The fluidic crystal display elements are arranged between two linear polarised plates (1, 4) positioned parallel to one another. Pref. a light-absorbing foil (8) is positioned behind the fluorescent plastics plate (5), at a small spacing from the latter.

Description

Basics of the invention

In the case of the known liquid crystal displays, a wide variety of Versions of the basic physical effect made use of the fact that light emitted by a The thin liquid crystal (= LC) layer occurs under the influence of a new electric field aut 'the latter is modulated. The modulation itself is extremely not electrical Tensions or services required. In principle, these passive FK displays can do that Ambient light modulleren and then have the further great advantage over the self-illuminating displays that their readability in a very wide brightness range is independent of the ambient brightness. In practice, however, it looks like that light bulbs are placed behind the displays to achieve acceptable legibility (Transmission operation), thereby creating decisive potential advantages of the passive Ads are not applicable. Or you use the ambient light in such a way that behind A mirror is placed on the display to reflect it through the cell emerging ambient light (reflection mode). This operating mode also only leads Satisfactory readability of the advertisements under restricted conditions. Under on the other hand, there is the annoying effect that the incident light casts a shadow caused by the display elements on the reflective surfaces. The possibilities of the newer field effect displays that require polarizers are due to the loss of light in the polarizers and severely affected by cast shadows. The present The invention proposes a new way of eliminating these disadvantages mentioned.

Summary of the Invention The essential idea of the invention is taking advantage of the fact that with the help of thin plastic sheets in which Fluorescent substances are dissolved, ambient light collects with high efficiency and can lead and can be dosed and visible at any location on the plate Re-leakage can therefore be caused by such a fluorescent spot, ' which is located behind a liquid crystal display acting as a light valve, height, Luminance that adapts to the ambient light and is electrically based on light transmission cause controlled display elements. By mixing fluorescent substances and using a pair of different selective polarizers can also create displays that can switch between 2 different colors.

Brief Description of the Drawings A brief description follows here of the drawings referred to in this patent application.

Fig. 1. Exploded view of a nematic LC rotary cell Fig. 2. Representation of the relative reflected intensity of unpolarized light, which meets an air-glass interface, depending on the angle of incidence Fig. 3. Representation of the relative reflected intensity of unpolarized light, that meets a glass-air interface depending on the angle of incidence Fig. 4. Exploded view of an electro-optical display using a fluorescent plate as an embodiment of the arrangement according to the invention Fig. 5. Simple types of light extraction shown using a cross-section through a fluorescent plate.

FIG. 6. The observation angle range is shown on the basis of a typical example depending on the ratio of the opening width on the fluorescent plate for the display green of the LC cell Fig. 7. Exemplary embodiment for a further Brightness-increasing curve of an LC display with the help of an additional reflector plate Fig. 8. Transmission curves for 3 different colored fluors available on the market Decorative plexiglass sheets Fig. 9. Fluoro essence emission curves for the same materials as in Clfig.8 Detailed Description of the Invention This here described method for brightness enhancement is particularly suitable for everyone FK effects, where between a light blocking and a translucent State can be switched by an electric field. This light valve effect LC effects applied to azoles in displays can be known with the aid of achieve additional polarizers and possibly passive optical elements. In the following, the operation of the device described here is only given in context described with a "nematic rotating cell". When using other LC effects the interaction with the device described here results for the person skilled in the art just like that.

The method shown in FIG. 4 for increasing the brightness of LC displays uses the electro-optical element of the nematic liquid crystal rotary cell, which is shown in Fig. 1 and is designated there with (10). This electro-optical Element has been described in German Patents No.

2 158 563 and No. 2 202 555 and only a brief summary is to be given here. The function of this element is to rotate the plane of polarization of a light beam that passes through the element by 90 ° when no voltage is applied to the element ("field off" state), and to leave the incident polarized beam unchanged "Field on" state. Fig. 1 shows a perspective view of the components that make up the nematic rotating element. This element consists of a nematic FR layer with positive dielectric anisotropy (5) enclosed between two parallel glass plates (3) and (7) on which a electrically conductive but optically transparent material, such as SL; 02, is applied to the inner surfaces (4) and (6). These inner surfaces, which have a typical distance between 5μ and SOg, serve as electrodes and are connected to a voltage source (9) via a switch (8). The electrodes can also be segmented in different ways, depending on the application, and provisions can be made to switch the voltage to different segment combinations. In this case, the optical rotary cell, which is sketched in FIG. 1, would only represent a part of the LC display, namely a specific pair of electrode segments. The surface of the transparent electrode (4) is specially treated, e.g. B. by rubbing with a fine polishing agent in one and the same horizontal direction in order to uniformly orient the preferred direction of the nematic FK-Schichi immediately adjacent to the electrode in this direction. The surface of the other trans- Parent electrode (δ) is treated accordingly, but the preferred direction of the immediately adjacent LC layer is vertical. If no voltage is applied to the electrodes, the local preferred orientation of the nematic liquid crystal rotates uniformly over an angle of 900 when one goes from one electrode to the other. If the plane of polarization of the light coming from the light source (1) and passing through the polarizer (2) is parallel (as shown in FIG. 1) or perpendicular to the adjoining LC layer, the plane of polarization of the light passing through the layer will be converging rotate with the twisted nematic structure, and exit again on the other side of the element rotated by 900 and are then absorbed in the second polarizer (11). If a suitable voltage (9) is applied to the electrodes, the preferred orientation of the nematic liquid crystal will reorient itself and lie essentially in the direction of the applied electric field. In this state, the light beam will pass through the element (10) without experiencing any change, and consequently the horizontally polarized light in (2) can now pass through the second polarizer (11).

The new type of component in connection with LC displays, which is described in the following referred to as a fluorescent plate will now be described.

For this we consider a flat Plexiglas plate a few millimeters thick with a smooth surface, in which a fluorescent substance is dissolved in such a concentration that, for example, the blue portion of the incident daylight is fully absorbed. Furthermore, this plate should have end faces running perpendicular to the plane of the plate, which should ideally reflect light so that no light can escape at the edges of the plate. According to FIG. 2, in which the relative reflected intensity for unpolarized light is given as a function of the angle of incidence, approx. 82% of the intensity enters the fluorescent plate with isotropic daylight distribution. For the re-emergence of the fluorescent light emitted, for example in green, from the plate, the reflection on the thinner medium is decisive> which is shown in Fig. 3 as a function of the angle of incidence an angle # angle of Totalreflexionαtot hits the interface, leaves the plate and the light of the remaining angular range remains in the plate as a result of total reflection. The angle of total reflection results from the relationship (for the refractive index o? of 1.49 for Plexiglas results = 420). The proportion of the fluorescent light that is not totally reflected, here referred to as the loss factor V for abbreviation, is (in the example n = 1.49, V = 25070).

All light emitted within the angular range of total internal reflection (75% in the example) is due to continued loss-free total reflection in the Plate plane (i.e. the mean direction of propagation is parallel to Plate level).

The fluorescent light captured in the fluorescent plate as a result of total reflection can now be redirected to a) reflective or b) light-scattering surfaces, which are attached to the fluorescent plate, caused to emerge from this plate will. Such specially attached surfaces are referred to below for abbreviation as Designated exit window. Simple types of such light extraction from one Fluorescent plates are shown in cross section in FIG.

Neglecting the aforementioned reflective and inevitable Re-exit losses and assuming that there are no other losses in the plate are present, the "brightness enhancement factor" i.e. H.

the factor that increases the luminance (= surface brightness) the exit window of the fluorescent plate compared to the luminance of a not fluorescent surface of the same color, essentially given by the Ratio of the light-absorbing area of the arrangement to the total area of the exit window of the fluorescent light.

The combination according to the invention of LC display and fluorescent plate will now be explained with reference to the embodiment of FIG. The arrangement exists from the FK cell (2) according to the functionality of the nematic rotary cell with individual electrically controllable electrode segments (3).

The electrode segments in the example allow numbers to be displayed using the 7-segment method. In the area of the digits are on the front and the A polarizer (1) and (4) are attached to the rear of the LC cell. The polarizers have mutually parallel polarization planes, behind the LC cell is the fluorescent plate (5) with the mirrored end faces (6a) to (8d) and the Exit windows (7). The exit windows simulate the electrode segments (3), however, their bar width is greater than the width of the electrode segment in order to avoid parallax to compensate between LC segments and exit windows. Everything closer to like the observation angle range of the display from the ratio of the exit window width to display segment width depends on a typical example in Fig. 6 with explanations shown. A light-absorbing plate is located behind the fluorescent plate (5) Foil (8) (not in optical contact with (5)), which serves the fluorescence plate, which naturally shows its own characteristic color in transmitted light so "black" to appear as possible and which has a positive effect on the contrast of the display. The excitation light passes through the LC cell in from all directions from the front the fluorescent plate and only where there are no polarizers. The fluorescent light leaves the plate (5) forwards in the direction of the LC cell through the exit window (7) Only such electrode segments (3) to which a voltage is applied become translucent, the others block the fluorescent light. Displayed In this case, digits appear light on a black background. So far it has been assumed that the polarizers (1) and (4) are neutral polarizers, that is, light of all wavelengths polarize in the visible range. You get an advantage if you instead 2 selective polarizers are used, which in the area of the excitation light both polarization directions let pass and only polarizer the rest of the spectrum. In this case it can the entire display surface can be used as a light collector surface, as the excitation light the polarizers happened undiminished.

Another special embodiment for the advantageous design the fluorescent plate is given in FIG. This embodiment is intended to demonstrate that there is also part of the surface of a housing in which an LC display is installed is, can easily be used as an additional light collector surface and so the The brightness of a display can be increased further. This is where the fluorescent plate is attached (1) with exit windows (2) an additional collector plate (3) made of fluorescent Plastic connected via a mirrored 45 ° end face (4) for coupling in light.

A further modification of the device according to the invention allows to switch it electrically between 2 different colors. To do this, the Fluorescence plate a 2-color mixture of fluorescent substances. So you send for example red and green fluorescent light off. All you need then is the polarizer (4) in Fig. 4 to be replaced by a combination of a horizontally polarizing one selective polarizer, which only leaves green light unpolarized, plus one vertical polarizing another selective polarizer that unpolarizes only red light leaves. Then there is the fluorescent light after passing through this polarizer combination of horizontally polarized red light and vertically polarized green light. As a result, the overall arrangement then leaves segments where there is no voltage only the green fluorescent light will pass while on the segments with tension only the red light can pass.

In Fig. 8 and 9, the light transmission curves and the fluorescence emission curves of 3 different colored fluorescent plates, as they are commercially available, are shown, on the basis of which the ideas according to the invention were tested enumerated and briefly commented on. The functions of the fluorescent plate in combination with the LC display are subdivided into A) light collection B) light propagation C) light extraction To A 1. Loss factor Proportion of the fluorescent light not totally reflected.

2. Fluorescence quantum yield = number of light quanta absorbed Number of light quanta emitted (should be as close as possible to 1).

3. Ratio of absorption bandwidth to emission bandwidth (if possible great; achievable by mixing fluorescent substances with different absorption bands which, however, have approximately the same emission band).

4. Fluorescent Substance Concentration Absorbed Intensity I = I 10- # Cd 0 I output intensity liter £ extinction coefficient, typical value 5 104 mol cm C Molar concentration of the fluorescent substance; upper reasonable limit for C is the concentration in the self-extinguishing of fluorescence is one mole, e.g. 10-3 Liter d layer thickness Easily achievable with 1 mm layer thickness full absorption of the Main absorption band.

5. Chemical (photochemical) stability of the fluorescent substance.

Re B 6. Reflectivity of the mirror layers.

For illustration: vapor-deposited aluminum layer: intensity reflectivity R = 0> 913. After 20 reflections, the intensity is 15% of the initial value sunk.

Evaporated silver layer: intensity reflection ability R = 0, 985.

After 20 reflections, the intensity has dropped to 73.5%. (R should be as close as possible to 1) 7. Absorption (and scattering) of the plastic matrix.

For a 4 mm thick clear Plexiglas plate, which is exposed to vertical incidence of light If 1% of the light is really absorbed, the light would already be after a running time of 40 cln should have dropped to 1 / e of the initial intensity. (Absorption should be as small as possible 8. Light scattering due to surface roughness or surface contamination.

Since the fluorescent light is much more often parallel to the plane of the plate Boundaries than is reflected on the mirrored end faces, it is particularly important on that these reflections are lossless d. H. in this case free of scatter get lost. The plates produced by injection molding generally meet this condition good.

Re C 9. Brightness amplification factor =, luminous surface 9. Brightness amplification factor = Light exit window area 10. Angular distribution of the emerging fluorescent light.

The angular distribution of the emerging fluorescent light depends on. on the type of coupling, which in turn affects the brightness of the display will. This will be explained briefly using the examples given in FIG. 5.

In Examples 1 and 4, the front plane surface determines the size the rau mwinkelbereich in which fluorescent light is refracted at all, namely 21; . In example 2, on the other hand, is the solid angle range of the exiting Light already restricted. You can get a closer look at these simple examples make clear the considerably different angular distributions.

11. Shaping of the reflective edges and the exit window so that the transit time of the light becomes short.

It is easy to understand that in the event that there are no losses occur in the lidite propagation, the type of light extraction and its effectiveness would have no influence on the luminance of the exit window. To the same extent as one approaches this ideal case, the requirements for the light decoupling s effectiveness lower.

The most favorable shape of the reflective surfaces of the fluorescent plate must be found empirically in each individual case. The rectangular shape is certainly always nice the cheapest.

Furthermore, it is easy to see that the light decoupling effect does not exist and uniform illumination of the exit window do not maximize at the same time permit. An adapted compromise must therefore be sought in each case.

Advantages of the Invention The described invention has many advantages compared to the known types of lighting, whereby the scope of LC displays is expanded.

The advantages of the invention are: 1. You can do without an additional light source achieve exceptionally high, previously unattained brightness with high contrast.

2. The readability of the display is within limits that have not yet been achieved regardless of the ambient brightness.

3. The displays are free from parallax and shadows.

4. The process also allows you to easily choose between 2 colors to switch.

5. The device is simple, cheap and flexible because the fluorescent Plastic plate because of its easy moldability by injection molding in any complex shapes can be manufactured cheaply, so that special display lighting requirements can easily be taken into account.

L e r s e i t e

Claims (11)

P a t e n t a n s p r ü c h: e 1. Arrangement for passive brightness amplification of single- or multicolor display devices that have a liquid crystal layer included, characterized in that behind the liquid crystal display device a fluorescent plastic plate mirrored at its end faces with light exit windows located associated with the display elements of the liquid crystal display device are. 2. Arrangement according to claim 1, d a d u r c h g e k e n n z e i 0 h n e t that the liquid crystal display elements are also located between two linear polarizers are located. 3. Arrangement according to claim 1 and 2, d a d u r c h g e k e n n z e i c h n e t that the liquid crystal display device is based on the principle of the nematic Rotary cell works. 4. Arrangement according to claim 1 and 2, d a d u r c h g e k e n n z e i c h n e t that the linear polarizers have a regularly shaped contiguous Form area which just covers the display elements, the remaining area of the liquid crystal display device but leaves free. 5. Arrangement according to claim 1, 2, 3 and 4, d a d u r c h g e k e n n z e i c h n e t that the polarization direction of the linear polarizers is parallel are oriented towards each other. 6. Arrangement according to claim 1 and 2, since dur 0 h g e k e n n z e i c Not that there are notches in the plastic plate for coupling out fluorescent light are attached, which are provided with a metallic-reflective coating. 7. Arrangement according to claim 1 and 2, d a d u r c h ge k e n n z e i o h n e t that light-scattering parquet pigments are used for the extraction of fluorescent light are attached to the plastic plate. 8. Arrangement according to claim 1, 2, 3 and 4, d a d u r 0 h g e k e n It should be noted that the Liohtaustrittsfenster on the plastic plate is the size and the shape of the polarizer surface on the liquid crystal display device and the polarization direction of the linear polarizers 900 is oriented to one another is. 9. Arrangement according to claim 1, 2, 3, 4 and 5, d a d u r c h g e k It is noted that selective polarizers are used as linear polarizers that leave only the fluorescence excitation light unpolarized. 10. The arrangement of claim 1, 2, 3 and 4, since you roh g e k e n n z e i c h e t that a mixture of fluorescent substances is dissolved in the plastic plate, that fluoresces in two different colors and one of the linear polarizers is replaced by a combination of two selective polarizers whose polarization directions 900 is oriented to one another, and the one color component perpendicular to each polarize other color component. 11. The arrangement according to claim 1 and 2, since you roh g e k e n n z e i c n e t that the fluorescent material in the plastic plate consists of a mixture of fluorescent substances is made up of which the absorption bands are different but have approximately the same emission band.