DE10129443B4 - lighting device - Google Patents

Abstract

Lighting device with a waveguide plate (1) and with a film arranged on the waveguide plate (1), the film (20, 20 ') being a prismatic film, with light being coupled into a narrow side of the waveguide plate (1), with a first side surface (4) light is coupled out of the waveguide plate (1), the refractive index of the film (5, 20), preferably the real part of the refractive index of the film (5, 20), being changeable and wherein on the first side surface (4) and on one the second side surface (15) of the waveguide plate (1) opposite the first side surface (4) is in each case arranged a film (5, 20) with a variable refractive index.

Description

State of the art

The invention relates to a lighting device according to the preamble of the main claim. Lighting devices are already known, in particular for the backlighting of liquid crystal displays, in which light is coupled into a side surface of a light guide and the light is coupled out in the direction of the display by light output elements arranged on the surface of the light guide. By variations of the light output elements, z. B. of microprisms, a homogeneous brightness of the display is achieved. From the DE 197 39 884 A1 a color screen is known in which the change in the luminosity of individual pixels by the application of the electro-optical Kerr effect is effected. In this case, however, the Kerr cell is to be introduced into the liquid crystal display and to be driven individually accordingly. It is also known to partially reflect waveguides to couple out light from the waveguide. However, this outcoupling method is not very efficient because of the losses in the light reflection, since the with the z. B. metallic reflection absorption leads to a damping of the evanescent wave and thus also to a weakening of the light waves in the waveguide plate.

From the EP 0 977 077 A2 For example, an optical device is known in which a light source of a light source is coupled to a flat side surface of a waveguide plate, a liquid crystal display is applied or structured in thin-film technology. By applying an electric field to the introduced liquid crystals, the refractive index of this layer or in the liquid crystal cell can be changed in such a way that an outcoupling of light from the waveguide plate is influenced.

From the JP 04-352 129 A For example, a display device is known in which a liquid crystal display for controlling the light extraction is arranged adjacent to a transparent plate.

From the post-published DE 100 34 484 A1 a device for illumination is known, wherein the optical fibers include electro-optical elements and wherein the device comprises a lamp which couples light into at least one of the optical fibers, the device being connected to a processor which controls the electro-optical elements in response to input signals, that the electro-optical elements are individually either in a switched scattering state for light extraction from one of the optical fibers or in a switched transpartent state for total reflection of the light in the optical fibers.

From the US 6,215,920 B1 For example, a reflective display is known in which light is coupled out of a waveguide plate via a prism structure and reflected by a reflector in which a structured electrophoretic material is applied to a transparent carrier.

Advantages of the invention

The lighting device according to the invention with the features of the main claim has the advantage that the light extraction can be influenced by avoiding losses by a film whose refractive index is changeable. For a flexible and efficient brightness control of a lighting unit is possible, in particular for the illumination of a display.

According to the invention it is advantageous that the film is a prism sheet. The prisms facilitate light extraction. In particular, the waveguide plate may also have a prismatic structure such that the prismatic foil has inverse prisms adapted to the prisms of the waveguide plate.

The measures listed in the dependent claims advantageous refinements and improvements of the main claim lighting unit are possible. It is particularly advantageous to subdivide the film into regions and to provide a variation of the refractive index independently adjustable for each individual region. This makes it possible to inhomogeneities z. B. caused by an arrangement of a light source on only one side of the waveguide plate, thereby compensate that the brightness is set differently in individual areas of the light guide plate by a local variation of the refractive index of the film. By varying the light distribution, it is also possible to emphasize individual areas of the display in comparison to other, darkened areas of the display. Preferably, in this case, the real part of the refractive index is changed predominantly.

Furthermore, it is advantageous to arrange electrodes on the foil, so that the refractive index of the foil is dependent on a voltage applied to the electrodes. As a result, in the case of a film whose material exhibits the Kerr effect, an influence on the refractive index can be realized in a simple manner.

Furthermore, it is advantageous to carry out the electrodes transparently, preferably from one transparent oxide, for. As indium-tin oxide, since this absorption losses are avoided at the electrodes.

According to the invention, it is advantageous to arrange films on both sides of the waveguide plate whose refractive index can be changed, since this allows the dynamics of the brightness control to be increased.

drawing

Embodiments of the invention are illustrated in the drawings and explained in more detail in the following description show:

1 , a first embodiment of a lighting device according to the invention,

2 , A second embodiment of a lighting device according to the invention and

3 , A particular arrangement of a film on a waveguide plate of a lighting device according to the invention.

Description of the embodiment

In the 1 is a waveguide plate 1 shown at the on a narrow side 2 a light source 3 is arranged. At a first side surface 4 the waveguide plate 1 is a foil 5 arranged. The foil 5 has a first area 6 and a second area 7 on, by a dashed line 8th is disconnected. In the first area 6 is on a first side surface 9 the foil 5 a first electrode 10 arranged. On a second side surface 11 that the first side surface 9 is opposite and the first side surface 4 the waveguide plate 1 assigns is a second electrode 12 the first electrode 10 arranged opposite. Likewise, on the side surfaces 9 . 11 in the second area 7 a third electrode 13 and a fourth electrode 14 arranged opposite one another, wherein the first electrode 13 on the first side surface 9 is arranged. The light of the light source 3 gets into the narrow side 2 the waveguide plate 1 coupled and extends approximately parallel to the first side surface 4 and to a second, the first side surface 4 opposite side surface 15 out. Light that on the side surfaces 4 . 15 is incident at an angle smaller than the critical angle of total reflection becomes in the waveguide plate 1 forwarded under total reflection. If the angle of incidence is greater than the critical angle of total reflection, the light leaves the waveguide plate at this point. The waveguide plate is this purpose preferably made of a transparent plastic material, for. B. of polymethylmethacrylate. The electrodes 10 . 12 . 13 . 14 are preferably made of a transparent, conductive material z. B. a transparent oxide, such as. As indium tin oxide, on the film 5 applied. About in the 1 not shown, either in wire form, as on the film 5 applied conductor tracks of a metal or also of a transparent, conductive oxide, the electrodes are connected to an electrical voltage. By in each case opposite electrodes 10 . 12 and 13 . 14 different voltages are applied, an electric field is generated between the opposing electrodes. The electric field acts on the film arranged between the electrodes, which is formed from a material which changes its refractive index as a function of the local electric field strength, that is to say the so-called Kerr effect. The foil 5 is preferably in optical contact with the first side surface 4 the waveguide plate. By applying the voltage, the refractive index of the film, which is preferably made of a suitable polymer, is thereby determined 5 increased. This increases the critical angle for the total reflection at the first side surface 4 the waveguide plate. As a result, a larger proportion of the light can escape from the waveguide plate. The ad will be brighter locally. If the electric field is lowered again, the refractive index of the film decreases 5 in the respective area 5 . 7 and the display becomes darker in the respective area.

In the 2 a second embodiment of a lighting device according to the invention is shown. At the second side surface 15 the waveguide plate 1 is a foil 20 arranged on one of the waveguide plate 1 repellent side a prismatic structure 21 arranged from prisms with a preferably triangular cross-section. The prism structure extends either as a longitudinal structure over the film 20 or has in each case pyramid-shaped individual prisms, which are arranged side by side. On the prism structure are electrodes 12 ' and 13 ' applied. At the first side surface 4 the waveguide plate 1 is a liquid crystal cell 22 arranged, which has a plurality of individual pixels whose light transmittance by means of an electrical influence on the individual pixels of the liquid crystal cell 22 is changeable. Details of the liquid crystal cell 22 are not shown in the drawing. From the prism structure 21 the light is directed towards the liquid crystal cell 22 steered, with the prism structure 21 the coupling of the light simplifies and the light in the direction of the liquid crystal cell 22 directs. The material of the film is chosen so that in a preferred embodiment without applied voltage, the material of the film 20 has the same refractive index as the waveguide plate 1 , By applying a voltage, the refractive index can be reduced. At an applied voltage, the boundary layer is between the waveguide plate 1 and the foil 20 optically inactive, so that lead in this case, the prisms to a light extraction. When applied voltage occurs while a total reflection at the boundary layer between the waveguide plate 1 and the foil 20 on, and the Auskoplungsseffizienz is reduced locally. The display will be darker in this case.

In the 3 is an embodiment of a waveguide plate 1' shown to a slide 20 ' is formed, wherein the waveguide plate 1' and the foil 20 ' an interlocking prism structure 30 form. Due to the interlocking prism structures, the dependence between voltage and display brightness in relation to the embodiment according to the 2 vice versa.

Whether the refractive index decreases or decreases with increasing local field strength and whether the field strength is to be applied parallel or perpendicular to a polarization vector and the wave vector of the light in the waveguide plate varies from material to material. However, knowing all of the tensor components of the second order nonlinear optical susceptibility of the material, the change in refractive index is predictable, so that a suitable material can be selected depending on the desired function.

In a further, not shown in the drawing embodiments is also possible to attach a film in front of and behind the waveguide plate. The two films can also be made of different materials. In this case, the films facing and / or facing away from the display can additionally have a prism structure.

Claims (5)

Lighting device with a waveguide plate ( 1 ) and with one on the waveguide plate ( 1 ), wherein the film ( 20 . 20 ' ) is a prism sheet, with light in a narrow side of the waveguide plate ( 1 ) is coupled, wherein from a first side surface ( 4 ) of the waveguide plate ( 1 ) Light is coupled out, the refractive index of the film ( 5 . 20 ), preferably the real part of the refractive index of the film ( 5 . 20 ), and wherein on the first side surface ( 4 ) and on one of the first side surface ( 4 ) opposite second side surface ( 15 ) of the waveguide plate ( 1 ) one foil each ( 5 . 20 ) is arranged with a variable refractive index. Lighting device according to claim 1, characterized in that the film ( 5 . 20 ) into areas ( 6 . 7 ) and that the refractive index of the film ( 5 . 20 ) for each area ( 6 . 7 ) is independently adjustable. Lighting device according to one of the preceding claims, characterized in that on the film ( 5 . 20 ) Electrodes ( 10 . 12 . 13 . 14 ) are arranged and that the refractive index of the film ( 5 . 20 ) from one to the electrodes ( 10 . 12 . 13 . 14 ) voltage is dependent. Lighting device according to claim 3, characterized in that the electrodes ( 10 . 12 . 13 . 14 ) are transparent. Lighting device according to one of the preceding claims, characterized in that the film ( 5 . 20 ) is composed of a polymer.

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