DE10127549A1 - Variation of radiation behavior in planar, light-guiding transparent body for e.g. lighting or information display, is achieved by varying refractive index locally - Google Patents

Abstract

Local, limited regions of varied refractive index (2) are produced. An Independent claim is included for corresponding equipment The panel (3), lit at the edges by surface-mounted LEDs, includes microlenses (2) formed as described, and arranged to represent information.

Description

Flat, light-guiding, transparent bodies are used for example edge-lit signs when conveying or displaying information.

There are already different versions of information display and display elements become known where information is stored on transparent, light-guiding media by coupling light by means of SMD LEDs arranged on circuit board strips be made visible in the side edges of a light guide body (cf. DE 43 11 018; DE 43 44,963; DE 195 13 185; DE 297 06 201; DE 298 20 384; DE 92 07 253 and DE 296 03 006).

These circuit board strips can be equipped with SMD LEDs in all colors including white be rigid, but also flexible.

The information to be conveyed is different on the surface of the light guide body Methods such as etching, milling, painting or coating applied. To increase the brightness of such information display and display elements, the circuit board strips can be embedded in reflector-like profiles. Waterproof and temperature-resistant solutions are available for outdoor applications available (DE 196 54 850).

For the decoupling of the light remaining in the medium due to total reflection at the media boundaries, the surface is changed and light emerges in a manner representative of these surface disturbances. FIG. 1a shows the physical background as the prior art. There is shown in Fig. 1a in the lower half of a transparent medium is provided with egg nem refractive index larger ( "optically dense medium"), than that of the symbolized in the upper half of the air ( "optically thin medium). The partial beams 1 , 2 and 3 are thrown back into the optically denser medium at the origin (place of impact of the rays), they experience total reflection.The critical angle (α _G ) of the total reflection follows from Snellius's law of refraction and corresponds to the beam with angle of incidence α ₁ (= α _G ), which does not leave the medium after the refraction under an exit angle 90 ° (α ₂ = 90 °), but instead disipers on the surface.

Partial beams that hit the interface at a smaller angle to the perpendicular are broken and leave the optically denser medium. This applies to the rays 4 , 5 and 6 designated in FIG. 1a. This type of information display is particularly disadvantageous in the case of large-area displays which convey a large amount of information. This reduces the transparency of the media for large-scale advertisements. The information on the surface is no longer protected against mechanical access and environmental influences. For this purpose, complex protective coatings or multi-layer systems must be used in which the light guide body is surrounded by protective panes. This is complex and makes the information display more expensive. In addition, the outcoupled light is scattered, i.e. in all directions in the room, i.e. also emitted to the rear. Directional radiation is not possible.

The purpose of the invention is to offer a solution which avoids these disadvantages.

The object of the invention is to propose a solution in which the transparency of the light guide the medium is not reduced by scattering effects and in the information and also functions are shown in such a way that the surface of the light guide body remains mechanically uninjured. Dar In addition, the information or functions should protect against mechanical access and environmental technology African influences should be protected, complex protective coatings should be eliminated and the light decoupling should have a higher brightness.

This object is achieved by the features in the characterizing part of the Main claim in connection with the features of the preamble.

Appropriate configurations of the inventions are contained in the subclaims.

A key feature of the new solution is that the information content of a Device for displaying or displaying information not on the surface is brought, but ge by special processes in the interior of the transparent medium is brought. This does not change the surface of the light guide body. If a material with a sufficiently resistant surface (e.g. mineral glass) is the Device for displaying or displaying information against environmental influences, Reini and mechanical interventions insensitive. The information is seen as a change in the trans parent medium inside, i.e. between the two surfaces, without changing them brought in. The coupling out of the coupled light takes place after a different effect principle, as in the publications belonging to the state of the art. With these it will Light coupled out by a surface disturbance,  the total reflection is destroyed at this point and the light emerges.

In the event of a local disruption or destruction of the surface, the light in all of these places Spatial directions scattered, there is no directional radiation.

In the facilities presented here to display information or to display the the same or generally for lighting, a part of the light rays of the internal Lichtwe redirected and distracted by a disturbance in the medium. The deflected light then hits at a different angle from the inside to the interface, that is, the total reflection condition conditions are no longer fulfilled. The light emerges from the medium. In contrast to The state of the art does not destroy the total reflection locally, but only locally bypassed.

The following applies:

For glass (n ₁ = 1) bordering air (n ₂ = 1.5) there is a critical angle of α _G = 42 °. All light rays that are at an angle to the perpendicular through a glass pane that borders on air remain in the glass.

The deflection by the refraction is determined by equation (1).

The essence of the invention is now that be locally described by the following delimited areas with changed refractive index light rays that are larger on paths at an angle Run more than the critical angle through the optically denser medium, be deflected and then hit the interface at a steeper angle, be broken and out of the medi to quit. The total reflection is not at any point on the surface due to changes (status technology) interrupted, only the beam path is ver for a small part of the light changes and so it is brought out.

These refractive index changes can be reduced by introducing energy into the Generate the shape of laser photons. The lasers used - mostly Nd: YAG lasers with one Wavelength of 1064 nm - are operated Q-switched. The pulse lengths are here  usually shorter than 10 ns. Because of the very high field strengths, it comes with the focus the laser beam to nonlinear self-focusing effects in the glass matrix. It will Electrons are released, which form a plasma, which then absorbs the laser beam. From the The glass is locally melted in this hot plasma. This is linked to generation local areas of tension. If the locally introduced tensions are too great, it happens at the well-known cracks in the glass. The laser parameters must therefore be suitable be chosen to avoid cracking.

The structure also changes due to the rapid cooling process condition of the glass, whereby both the volume and the refractive index change to due to the rapid heating and cooling process. In addition to the pure refraction The remaining tension after the cooling process leads to a localized area with stress birefringence. Another alternative way to Achievement of refractive index changes in the transparent medium is by diffusion pro of certain ions. This technique is used in the field of beam guidance uses to guide and collimate radiation. In contrast to these gradient index lenses (GRIN lenses), which are used, for example, for collimation of laser diode radiation or for imaging are used in endoscopic devices, the introduced indexes stand out changes in that they cause the radiation to escape from the transparent medium act, the exit surface of the radiation is not parallel to the entrance surface.

Another essential feature of the present solution is the provision of a Device with a light-conducting transparent body produced by the method is equipped, in the SMD-LED light arranged on PCB strips in the Kan is coupled into the body. This device is preferably suitable for illustration of information or to display it. This facility combines the essential Advantage in that the information to be conveyed is no longer applied to the surface got to. According to the new principle, the directional production of special means that the Bre change the angle of view in the medium, so that these funds are also carriers of Infor mations are. The partial destruction of the surface to exit the rays can thus ent fall. Another major advantage of this solution is that the means directed to the partial change in the angle of refraction and introduced specifically can. This also has the advantage that significantly higher brightness levels with randbe illuminated signs can be achieved.  

This solution provides facilities for displaying information or for displaying it ben realizable, where different information represents in different directions are cash. This opens up new possibilities for signs, for example in danger situations give the viewer some other information that was not previously visible.

Another way is to have different information in different directions with different colors. This solution variant also opens up new possibilities for information or hazard signs, as there is now more information on one sign can be represented.

In addition, this specially trained transparent light-guiding body opens with the the means for deflecting the light beam is provided, new possibilities in lighting performance technology. Through these means, which are preferably in the form of microlenses, which change effect of the beam path, light decoupling can be realized with a brightness that were not possible according to the prior art while maintaining transparency. The esp special due to the directional beam path and thus a directional light coupling te higher brightness offers the possibility of such a prepared light-guiding transparent To use the body as a flat illuminant and especially with this body new solder approaches for effective and especially new energy-saving lamps gen. Since the surface of the facility is no longer damaged by the new process the illuminants to be created can be used both indoors and outdoors.

The lighting means can be designed, for example, as a light curtain for the window be, which preferably illuminates the room in the dark when illuminated. A white Another option is that of an illuminated screen. Finally, the lamp can be used as luminous room object to be placed in the room itself.

Due to the directional arrangement of the microlenses in the light guide, there is partial illumination or lighting spots can be realized indoors and outdoors. This variant offers that is, the possibility to illuminate selected areas. So the designer is a Hand in hand with attention to special features by means of subtle lighting do. In addition to preferred use in the advertising industry, the lamp can also be used in the The present form can also be offered as a separate product for the living area.  

Depending on the directional arrangement of the microlenses, the illumination spots can also be used in ver different directions can be realized indoors and outdoors.

Thanks to an additional colored light coupling, there are also different lighting spots Directions can be displayed with different colors both indoors and outdoors.

By using different light sources than the SMD- arranged on PCB strips LEDs for edge radiation and through the new light guide with the preferably as Means formed by microlenses can be used to realize an illuminant with which new We can be accessed in the information display and lighting.

The lighting means can, for example, by a defined arrangement of the means designed as microlenses the light that emanates from an external light source in the Change the beam path so that information can be displayed.

It is also possible to design the lighting means as a curtain for the window partial illumination or lighting spots in the interior and exterior space realized. Sunlight is preferably used as the light source. at The use of sunlight can be the means which are preferably designed as microlenses be arranged that a time of day changing information display or lighting is feasible.

Through a defined arrangement of the means, which are preferably designed as microlenses Dispersion effects can be harnessed, which translate the light into its color disassemble components and distract them in different directions. That is information Representations and lighting can be realized in different colors and directions.

Another possibility is a defined arrangement, preferably as microlenses formed means such that preferably narrow strips of preferably similar or almost similarly distracting means in front of a monitor or other imaging device or in the front window of such a device can be integrated and displayed image information are preferably directed to these areas in strips. By the same distraction by means of the generated means two different ones can be created for the viewer of the image information Realize images for each eye so that a stereoscopic impression with a spatial Perception is possible. The drawing files and the corresponding, distracting means must sen not necessarily be arranged in strips, there are also random arrangements z. B. with stochastic distribution possible.

The invention is based on the drawing in principle for the sake of example he even closer to be refined.

In the accompanying drawing:

FIG. 1b shows the dependence of the exit angle of the beam from the entrance angle;

Fig. 2, some microlenses in a microscope photograph;

Fig. 3 shows a further view of microlenses in specific arrangement thereof;

Fig. 4 microfractures shown in a microscope photograph;

5a is a simulation of an illumination with a conventional desk lamp arranged in the background artificial unlit window curtain.

Fig. 5b is a simulation of lighting with an artificial illuminated window curtain, which is provided with microlenses and is coupled into the light with SMD-LED.

Fig. 6 sketchy the principle of action for stereoscopic vision.

FIG. 1b shows the exit angle of the light beam as a function of the entrance angle. The angles in the diagram refer to the angle between the beam and the interface. If the rays are incident at angles that are greater than the critical angle (dashed line at approximately -40 °), total reflection occurs: "Entry angle is equal to exit angle". If the limit angle is undershot, the beams are refracted towards the plumb and leave the optically denser medium at a different angle. This dependence describes Snellius' law (1).

Fig. 2 shows in a microscope image illuminated with polarized light some of these ge local areas formed, which have the shape of microlenses. Illumination with linearly polarized light makes the fuses visible in the first place; with normal or monochromatic illumination, the microlenses are not visible. Lenses of different sizes can be seen on the image, the size can be varied by a factor of two. The smallest lenses to date can be seen in a small group on the sketch at the bottom left, the largest almost exactly in the middle of the picture. The flower-like expansion is not the geometrical shape of the lens itself, but the tensions carried by the melting into the environment, which lead to the stress birefringence mentioned.

FIG. 3 shows a series of lenses, again made visible by illumination with linearly polarized light. It can be seen that with the same process parameters, the lenses and the voltages generated in the environment are extremely uniform.

This is another very important point of this solution compared to the state of the art nik, where the micro-fractures generated by laser can already be seen with the naked eye take different forms.

Fig. 4 illustrates a further microscope image, in which some micro breaks are Darge, which differ greatly in their structure. You can clearly see the cracks that extend from a central point into the surrounding glass matrix.

FIGS. 5a and 5b show the simulation of an illuminated with special light-conducting offices. In Fig. 5a shows how the lighting situation in today's normal case with a simple desk lamp presents itself as illumination means being visible in the background a non-illuminated artificial light curtain. In Fig. 5b in the manner presented here prepared glass surfaces in the form of light-guiding bodies which hang in front of the window in an switched-on state and the effect on the room illumination are shown. The simulation shows little difference to a situation during the day when the light is not dazzling, e.g. B. with light cloud cover. Experiments with light extraction have also been able to confirm this result quantitatively. The outcoupling areas can be structured so that the light can be outcoupled in the form of the information to be displayed, even with high brightness, without dazzling.

With this type of decoupling of light, a wide variety of information devices are represented position, for display and lighting with edge-blasted light from SMD LEDs or other light sources conceivable.

The special type of this light decoupling allows a determination of the decoupling direction of the Light, unlike the state of the art. Usually the light is turned on by scattering Interface phenomena taken from the transparent medium, the scattering takes place without Directional pattern evenly in all spatial directions. A large part of the light goes with it lost for information display because it does not reach the eye of the beholder. With a directional decoupling, as offered by the solution presented here, can provide information straightened from a surface unchanged medium. It is also possible, integrate different directional characteristics in a transparent medium.

The directional radiation only enables the use of such devices for lighting tung.  

The light radiated in at the edges can be coupled out evenly over a large area and e.g. B. blasted partly on the ceiling of a room and partly on the floor without direct light falling on the viewer. The fact that the surface surface of the transparent medium has not been changed, it remains crosswise in viewing directions transparent for light conduction, even if light emerges because there is no scatter, but only directional decoupling. This directional light decoupling enables new types Applications. Such a novel application can consist of window panes, that allow the view outside unchanged, at the same time light on the ceiling when needed or drop on a piece of furniture. That would be even if the light was on View outside unchanged, as long as you are not directly in the decoupled light looks. Further new applications are emerging for hazardous areas. So it is for Example possible that a transparent pane if necessary a bright escape route marking on the floor without this information being switched off on the Disc is visible. Due to the radiation characteristic of the coupling, which is limited in solid angle Mechanismes can display information depending on the location of the viewer, Guidance systems or the like are conceivable here. By multicolored coupling z. B. Location-dependent color or information displays possible. This makes completely new ret route or danger point markings possible with the current state of the art cannot be realized. The fact that directional radiation can also be used in very thin glasses bring in connection with the light coupling through very small in their design SMD LED conductor strips the possibility to build backlighting elements that define a th viewing area and thus in this high contrast and brightness. Anwen The backing and lighting of display displays are very general. By the very high efficiency and the almost unlimited lifespan of the SMD LEDs are sol che lighting elements especially for portable, so off-grid devices of large Be interpretation. This new technology can also be used to illuminate very large areas produce an extremely uniform and pleasantly flat lighting without annoying Can generate point light sources in a room or in outdoor applications. The local very limited areas with changed refraction can also be divided into thin media in several Introduce layers so that different levels of information are superimposed in one medium are embedded, which can also be operated independently of one another.

Fig. 6 shows the principle of operation for stereoscopic vision by using a suitable arrangement of the microlenses 2 in the transparent body 3. For each eye 5 , a partial image 1 a; 1 b in the image generator 1 generated and shown. When passing through the transparent body 3 provided with microlenses 2 , the partial images 1 a; 1 b uniformly deflected in different directions 4 . The partial images 1 a appear to the viewer; 1 b under different viewing angles, so that a spatial impression is created.

Claims (29)

1. A method for changing the radiation behavior in a flat, light-guiding, transparent body, characterized in that locally limited areas with a changed refractive index are generated. 2. Method for changing the radiation behavior in a flat, light-guiding, Transparent body according to claim 1, characterized in that the locally limited Be rich are formed by producing microlenses. 3. Method for changing the radiation behavior in a flat, light-guiding, Transparent body according to claim 1 and 2, characterized in that microlenses through Refractive index changes and / or changes in voltage birefringence with one Laser suitable parameters are generated. 4. Procedure for changing the radiation behavior in a flat, light-guiding, transparent body according to claim 1 to 3, characterized in that the individual Bre Changes in index and / or changes in voltage birefringence with several Laser pulses are generated. 5. Method for changing the radiation behavior in a flat, light-guiding, Transparent body according to claim 1 to 4, characterized in that the refractive dex changes and / or changes in voltage birefringence with a temporal and / or spatially and / or spectrally specially shaped intensity distribution of the laser radiation - be generated. 6. Procedure for changing the radiation behavior in a flat, light-guiding, transparent body according to one or more of the preceding claims, characterized records that the refractive index changes and / or the changes in voltage doubles Refractions due to concentration gradients of certain atoms or ions in the glass matrix generated and a partial emission of radiation through a surface that is not par allel to the entry surface is effected.   7. Process for changing the radiation behavior in a flat, light-guiding, transparent body according to one or more of the preceding claims, characterized indicates that the concentration gradients are generated by diffusion processes and a partial emission of radiation through a surface that is not parallel to the entrance surface lies, is effected. 8. Procedure for changing the radiation behavior in a flat, light-guiding, transparent body according to one or more of the preceding claims, characterized shows that the concentration gradients are generated by purely chemical processes. 9. Method for changing the radiation behavior in a flat, light-guiding, transparent body according to one or more of the preceding claims, characterized records that the concentration gradients are introduced by electrochemical processes the. 10. Method for changing the radiation behavior in a flat, light guide the, transparent body according to one or more of the preceding claims, characterized characterized that the concentration gradients by evaporation or sputtering processes be fathered. 11. Device with light-guiding, transparent body with areas with modified Bre chung index, which was prepared by the method of claims 1 to 10, and in which the side edges or in the vicinity of SMD LEDs arranged on circuit board strips are provided, characterized in that by arranging the generated means, which are, for example, microlenses, in the form of information. 12. Device with light-conducting, transparent body according to claim 11, characterized records that it by a spatially defined arrangement of the generated means, for. B. in Art the microlenses, representing different information in different directions forms is. 13. Device with light-conducting, transparent body according to claim 11 and 12, characterized characterized that they with a defined arrangement of the funds generated, the z. B. Micro Lenses are different information in different directions with different colors is designed to be representative.   14. Device with light-conducting, transparent body according to one or more of the claims che 11 to 13, characterized in that they are generated with a defined arrangement Means z. B. are microlenses, a flat lighting device for indoor and outside space is. 15. Device with light-conducting, transparent body according to claim 14, characterized records that the brightness by the density of the medium formed in the medium, the z. B. Micro are lenses, and / or can be varied by the density of the arrangement of the SMD LED. 16. Device with light-conducting, transparent body according to one or more of the claims che 11 to 15, characterized in that it is defined by the spatial and its location arranged means, which are microlenses, for example, a flat illumination medium for partial lighting or lighting spots indoors and outdoors. 17. Device with light-conducting, transparent body according to one or more of the claims Chen 11 to 16, characterized in that it is defined by the spatial and its location arranged means, which are microlenses, for example, a flat illumination medium for partial lighting or lighting spots in different directions in the Indoor and outdoor space is. 18. Device with light-conducting, transparent body according to one or more of the claims Chen 11 to 17, characterized in that it is defined by the spatial and its location arranged means, which are microlenses, for example, a flat illumination medium for partial lighting or lighting spots in different directions different colors in the interior and exterior. 19. Device with light-conducting, transparent body according to one or more of the claims che 11 to 18, characterized in that they consist of several light-guiding transparent Bodies equipped with means for changing the angle of refraction, in Layered construction exists. 20. Device with light-guiding, transparent body with areas with modified Bre chungsindex, which was prepared by the method of claims 1 to 10, thereby ge indicates that the light guide body is designed to be radiating and the optical path for Partial beams is changeable.   21. Device according to claim 20 with light-conducting, transparent body with areas changed refractive index, which was prepared by the method of claims 1 to 10 de, characterized in that they are generated by a spatially defined arrangement of the Means, e.g. B. in the type of microlenses, different information in different Rich lines is formed to represent. 22. Device according to claim 20 with light-conducting, transparent body with areas changed refractive index, which was prepared by the method of claims 1 to 10 de, characterized in that it with a defined arrangement of the generated means that z. B. microlenses are different information in different directions with different NEN colors is formed. 23. Device according to claim 20 with light-conducting, transparent body with areas with changed refractive index, which was prepared by the method of claims 1 to 10 de, characterized in that it with a defined arrangement of the generated means that z. B. are microlenses, a flat lighting device for indoor and outdoor space is. 24. Device according to claim 20 with light-conducting, transparent body with areas with changed refractive index, which was prepared by the method of claims 1 to 10 de, characterized in that they are defined by the spatial and their position th means, which are for example microlenses, a flatly designed lighting means for is partial lighting or lighting spots in the interior and exterior. 25. Device according to claim 20 with light-conducting, transparent body with areas changed refractive index, which was prepared by the method of claims 1 to 10 de, characterized in that they are defined by the spatial and their position th means, which are for example microlenses, a flatly designed lighting means for partial lighting or lighting spots in different directions indoors and Outside space is. 26. Device according to claim 20 with light-conducting, transparent body with areas changed refractive index, which was prepared by the method of claims 1 to 10 de, characterized in that it consists of several light-conducting, transparent bodies that are equipped with the means for changing the angle of refraction, in a layered construction consists.   27. Device according to claim 20 with light-conducting, transparent body with areas changed refractive index, which was prepared by the method of claims 1 to 10 de, characterized in that it is preferred by an arrangement of the generated means wise microlenses are formed in the form of lithographically useful information. 28. Device according to claim 20 with light-conducting, transparent body with areas changed refractive index, which was prepared by the method of claims 1 to 10 de, characterized in that the generated means, which are for example microlenses, before Image information, in particular monitors and television sets, are arranged. 29. Device according to claim 20 with light-conducting, transparent body with areas changed refractive index, which was prepared by the method of claims 1 to 10 de, characterized in that it is designed in front of mutually associated parts of image information, especially monitors and televisions, areas with the same type ger expression of the generated means, which are for example microlenses, are arranged.