DE19844921A1 - Flat lighting device has optical system that influences spatial light distribution of light to be coupled into plate to have at least one maximum in defined angular range wrt. optical axis - Google Patents

Abstract

The lighting device has a discharge lamp (9), an optical system (10) and a light conducting plate (11). An optical axis (A) is defined to lie in the plane of the front side of the plate and form a right angle with the lamp's longitudinal axis. The light from the lamp passes through the first narrow side of the plate into the plate, through the front of the plate and out of the plate. The optical system influences the spatial light distribution of the light to be coupled into the plate so that, viewed in the cross-sectional plane of the lamp, the light distribution has at least one maximum at an angle to the optical axis whose absolute value is not less than arctan(d/L), where L is the length of the plate and d its breadth.

Description

Technical field

The invention relates to a flat lighting device with a discharge lamp with aperture, an optical system and a light guide plate te.

Discharge lamp, optical system and light guide plate are so open geometrically matched and arranged to each other that light the lamp through at least one narrow side ("edge", "edge") of the light circuit board can be coupled into it (so-called "edge Light technology "). By reflection on one on the underside of the light guide This diffuse reflective layer is applied to the plate entire front of the light guide plate through to the outside and thus acts as a flat, expanded according to the dimensions of the light guide plate Light source.

Furthermore, the discharge lamps used are in particular especially around fluorescent lamps with tubular, closed on both sides Discharge vessel, the wall of which is at least partially illuminated fabric is coated. These lamps are also used to increase the Luminance along its longitudinal axis on the inside or outside of the Provide lamp vessel with a reflector for visible light, which ent along the longitudinal axis over a defined area. To this An aperture is created through which the light of the lamp passes  reaches the outside (aperture lamp). The lamp vessel can be rod-shaped, but also angled, for example L-shaped or U-shaped. In the last named case, the light from the lamp over two or three of the edges of the Light guide plate coupled into this.

Such lighting devices are used, for example, for back lighting processing of displays, in particular liquid crystal displays (LCD = Liquid Crystal Display) but also large billboards. Liquid crystal display There are many uses, for example in control rooms and cockpits of aircraft and increasingly also motor vehicles, in consumer electronics and as screens for personal computers (PC).

State of the art

US 5,055,978 discloses a flat lighting device with a rod-shaped aperture fluorescent lamp. Between lamp and light guide plate is arranged a trapezoidal plexiglass wedge, which contributes to the losses the coupling of the lamp light into the light guide plate should reduce. The width of the aperture is so far below the thickness of the light guide plate chosen that the light with the help of total reflection within the ple xiglass wedge can be guided from the lamp to the light guide plate.

Presentation of the invention

It is an object of the present invention to provide improved flat lighting device to provide.

This object is solved by the features of claim 1. Especially advantageous configurations can be found in the dependent claims.

For a better understanding of the explanations below, it is helpful to define an optical axis. This is - in a cross-sectional representation  the lighting device viewed - perpendicular to the longitudinal axis of the The lamp is oriented and runs parallel to the front of the light guide plate. The light coming from the lamp is essentially in the direction the optical axis is coupled into the light guide plate and then out as useful light through the front of the light guide plate couples.

The starting point of the following considerations is the realization that for as large a part as possible that is coupled into the light guide plate Radiation the requirement for total reflection within the light guide plate must be fulfilled. Because only this part and that part of the after In any case, entry into the light guide plate directly hits its underside can on the underside of the light guide plate arranged diffuse Re reflector and reflected through the front and useful white be forwarded. The rest is lost for the actual application.

Studies have now shown that the radiation characteristic of aperture lamps without additional measures is very similar to a Lambert distribution, i.e. the angle-dependent intensity distribution of a small area from the illuminated area of the aperture follows the relationship I (α) = I ₀ .cosα, where α den Paint angle between the Flächennor and the relevant light beam with the intensity I (α) and I ₀ denotes the maximum intensity in the direction of the surface normal of the partial area (α = 0). In other words, aperture lamps emit most of their luminous flux in the forward direction.

This leads undesirably especially when using lamps de diameter and aperture width comparable to the thickness of the light guide terplatte is that a significant proportion of the radiation no total reflection xion experiences within the light guide plate, but essentially on the  the narrow surface of the light guide opposite the light entry surface hits the plate and gets lost at some point. The curvature of the surface the discharge tube plays only a subordinate role here, d. H. the area The normals of all surface elements of the aperture are approximate oriented parallel to each other and to the optical axis.

On the other hand, efforts are made to make the width d of the aperture as possible choose large, since the luminous efficacy and the luminous flux are smaller the ratio b / D between aperture width b and lamp diameter this D drops significantly.

The loss of light mentioned can be significantly reduced if you take the Distribution of the light which is coupled into the light guide plate, deliberately changed. According to the invention, the proportion of radiation that otherwise directly through the light guide plate and for use radiation is lost on the portion that is inside the light guide plate is totally reflected, redistributed.

This procedure also makes it possible for the first time with edge light technology of the luminous flux increasing with the lamp diameter D of Lamps with on the wall of the discharge tube parallel to the tube length Axes arranged to actually benefit. These lamps are operated by means of dielectric barrier discharge. By ver The larger the diameter of such lamps, the namely increases Stroke distance, the power that can be coupled in and consequently the luminous flux. For further details on the concept of "dielectric barrier discharge" and especially the pulsed ones that are recognized as particularly efficient Electrically disabled discharge is referred to WO 94/22975. Au In addition, on the German patent application 197 18 395.6-33 the same Applicant referred to in the possibility of increasing the  Luminance of the lamp aperture when using more than two elec troden is disclosed.

According to the invention, the flat lighting device has an optical system which specifically influences the light distribution of the light to be coupled or coupled into the light guide plate in such a way that it has at least one maximum in the angular distance β, measured from the optical axis, and fulfills the following relationship:

where L is the longitudinal dimension (i.e. the dimension in the direction of the opti axis) of the light guide plate and d is its thickness.

The schematic sectional view in FIG. 1 illustrates this concept using a light distribution curve 1 with two maxima 2 , 3 , which form the angles β ₁ and β ₂ with the optical axis A. Starting from an origin 0 on the optical axis, one can imagine fictitious arrows that end on the light distribution curve 1 . The length of an arrow is then a measure of the light intensity in the direction of the respective arrow. The two longest arrows 2 ', 3 ' correspond to the two maxi ma 2 , 3 mentioned and consequently include the angles β ₁ and β ₂ with the optical axis se. The amounts of the two angles β ₁ and β ₂ can be the same or different. The light is coupled with this distribution in the light entry surface 4 of the light guide plate 5 .

In contrast to this, the prior art has a light distribution curve ve 6 with only a maximum 7 , which is collinearly oriented (β bezüglich 0) with respect to the optical axis A. Consequently, a large part of the radiation goes immediately, ie without total reflection, through the light guide plate 5 .

According to the invention, the optical system can also be an integral part of the Be light guide plate. For example, the light entry surface of the light Provide the circuit board with a V-shaped, parabolic or similar cutout be so that in each case a large part of the incident light rays upon entry broken into the plate towards its front or base side becomes. For further details, reference is made to the exemplary embodiments sen.

In addition, the optical system can also be part of the lamp for example, in which the aperture is divided in two such that one is the visible one Radiation-reflecting web which separates the two partial apertures that separates, parallel and centrally to the light entry surface of the light guide plate is oriented. As a result, two luminance maxima are achieved in a simple manner generates the required angles to the op table axis. In this variant, the pipe support is advantageous discharge cross-section shaped as drops, for example by deep drawing. The two partial apertures are then in the narrow range Curvature of the tube profile, however, arranged the electrodes in the area the wide curvature. On the one hand, this allows for the intensity maxi ma of the two partial apertures, each one corresponding to the relationship (1) Realize β angle, as is the case with pipes with a circular cross would otherwise only be possible with relatively small diameters. Ande on the other hand, as desired, a large stroke distance can still be achieved, corresponding to a relatively large diameter in the case of a pipe circular cross section. For further details, please also refer to the Reference examples.

For the advantageous effect of the invention, it is irrelevant whether the opti cal system as a transmissive element on the side facing the lamp the light guide plate or as a reflective element on the abge  facing side of the light guide plate is arranged. More on this is also executed in the exemplary embodiments.

In addition, cylindrical lenses and / or direction are for the optical system changing foils (e.g. Directional Turning Films from POC Physical Optics Corporation or Image Directing Films from 3M), Fresnel or prism foils and holographic diffusers, the distribution gene with two or more club-like maxima (Tedesco et al .: Holographic Diffusers for LCD Backlights and Projection Screens; SID 93 DIGEST, pp. 29-32).

Finally, the system can be explained on the basis of the above Optimize principles with so-called ray tracing processes. Goal of the Opti It is the backlighting properties of the lighting pre direction, d. H. ultimately, the level and uniformity of the luminance maximize on the front of the light guide plate.

An optical reflector is optionally provided to cover the space between the Aperture of the lamp and the light entry surface of the light guide plate enveloped.

In an advantageous embodiment of the flat lighting device a discharge lamp with an aperture is provided which is used for operation dielectric discharge is suitable.

In the sense of the greatest possible increase in the luminance of the front the light guide plate is the diameter of the lamp within the framework of the bauli Chen options (installation depth) chosen accordingly large, preferred equal to or greater than the thickness of the light guide plate.

In a preferred embodiment, the tubular lamp has two stripes fen-shaped electrodes on the inner or outer wall of the Discharge vessel of the lamp parallel to the tube longitudinal axis and to each other  are arranged diametrically. In this way, the large lamp is lit. knives specifically for the corresponding maximum possible stroke distance of the Discharged. With increasing stroke distance also increases the operating voltage for the dielectric barrier discharge and consequently the electrical power that can be coupled in. With the help of the pulsed Be finally, according to WO 94/22975, this leads to the desired result the above-mentioned increase in lamp luminous flux.

As the light output, as already mentioned, with a decreasing ratio nis b / D clearly between aperture width b and lamp diameter D. decreases, the width d of the aperture is simultaneously made as large as possible chooses. The width of the aperture preferably corresponds approximately to the thickness of the Light guide plate.

Further preferred ranges for the ratio of aperture width b to Dic ke d of the light guide plate are b / d <0.6, 0.8 and 1.

Description of the drawings

In the following, the invention will be based on several exemplary embodiments forth be explained. Show it:

Fig. 1 is a schematic sectional view for explaining the principle of the invention using a light distribution having two maxima,

Fig. 2 is a schematic sectional view showing the prior art,

Fig. 3 is a schematic sectional view of a loading invention leuchtungsvorrichtung V-profile light entrance face than trans missives optical system,

Fig. 4 is a schematic sectional view of the light guide plate having the V-profile light entry surface in detail,

Fig. 5 is a schematic sectional view of a loading leuchtungsvorrichtung invention with two-part aperture as a transmissive optical system,

Fig. 6 is a schematic sectional view of a Be lighting device according to the invention with a reflective optical system.

Fig. 3 shows a schematic sectional view of a flat lighting device 8 for the backlighting of liquid crystal displays (not shown), consisting of an aperture fluorescent lamp 9 , a trans missive optical system 10 and a light guide plate 11th

The fluorescent lamp 9 consists of a tubular discharge vessel 12 , two electrodes 13 , 14 and a functional layer system. The layer system consists of a reflection layer 15 made of TiO ₂ and a phosphor layer 16 made of a three-band phosphor. The three-band phosphor consists of a mixture of the blue component BaM gAl ₁₀ O ₁₇ : Eu, the green component LaPO ₄ : Ce, Tb and the red component (Y, Gd) BO ₃ : Eu. The resulting color coordinates are x = 0.395 and y = 0.383, ie white light is generated. The reflection layer 15 is applied directly to the inner wall of the discharge vessel 12 , where an aperture 17 of width b = 8 mm is left out. The phosphor layer 16 is applied to the reflection layer 15 or in the area of the aperture 17 directly on the inner wall of the discharge vessel 12 . The outer diameter of the discharge vessel 12 made of glass is approximately 14 mm with a wall thickness of approximately 0.5 mm. The length of the tubular discharge vessel 12, which is sealed at its two ends with a dome (not shown) formed from the vessel material, is approximately 27 cm. Within the discharge vessel 12 there is xenon with a filling pressure of approx. 170 hPa. The two electrodes 13 , 14 are designed as metal strips which are arranged on the inner wall of the discharge vessel 12 parallel to the longitudinal axis of the tube and diametrically opposite one another. In this way, the maximum possible stroke distance w in a tubular discharge vessel is used for the discharge and, as he explained at the beginning, a correspondingly high luminous flux of the lamp is achieved. Both electrodes 13 , 14 are covered with a dielectric layer 100 made of glass solder.

The light guide plate 11 consists of a flat plexiglass block of thickness D = 10 mm, the width B = 27 cm in the direction of the lamp longitudinal axis and the length L = 20 cm perpendicular to the lamp longitudinal axis. A first 18 of the four narrow sides of the light guide plate 11 is arranged parallel to the longitudinal axis of the fluorescent lamp 9 and opposite its aperture 17 . For the sake of simplicity, the first narrow side 18 is referred to below as the “leading edge”. In addition, the fluorescent lamp 9 and the Lichtleitplat te 11 viewed in the sectional view are aligned centrally to each other, ie on both sides of an imaginary center line or optical axis A, the width b of the aperture 17 is only about 1 mm smaller than the thickness d of the light guide plate 4 ( ^d / ₂ - ^b / ₂ = 1 mm). The width b of the aperture is approximately the same as the thickness d of the light guide plate.

In the area of the leading edge 18 of the light guide plate 11 , the optical Sy stem 10 is integrated. It consists of a notch which is V-shaped in cross section and extends over the entire length of the leading edge 18 . For the details of the optical system 10 and its mode of operation, reference is made to FIG. 4 and the associated description.

In a variant, not shown, a cylindrical lens is immediately in front the leading edge arranged in order to minimize the coupling losses to keep.

In FIG. 4, the light guide plate 11 is shown in FIG. 3 with the major integrated optical system 10 and with some of explaining the erfindungsge MAESSEN dimensioning parameters again in detail in a side view. As an example, a light beam 19 incident parallel to the optical axis A is drawn, which strikes the lower slope 20 of the V-shaped notch 10 of the light guide plate 11 at an angle α to the perpendicular. The beam 19 is refracted towards the plumb line as it enters the light guide plate 11 . In the plate of the beam 19 'forms the angle β with the solder, accordingly an angular deviation γ to the incident beam 19, and is incident at the angle = 90 ° -y relative to the perpendicular to the base surface 21 of the Lichtleiterplat te. 11 The requirement of total reflection is fulfilled for all rays for which <α _G applies, where α _{G is} the material-dependent critical angle of total reflection. For example, for a plexiglass plate with a thickness of d = 10 mm, a depth of s = 2 mm is sufficient.

Fig. 5 shows a schematic sectional view of another example of a flat lighting device 21 with a transmissive optical system. The same features as in FIG. 3 are provided with the same reference numbers. The optical system is here integrated into the aperture lamp 22 and consists of a two-part aperture with the two partial apertures 23 , 24 , which are arranged on both sides of the optical axis A and are separated from one another by a reflective layer strip 25 . The two apertures 23 , 24 generate a light distribution with two maxima each in the desired angular distance β ₁ and β _{2 from} the optical axis A, according to the angular relationship mentioned in the general description part. As a supportive measure for splitting the light distribution into two maxima, the tubular discharge vessel has a drop-like cross section. The reflecting layer strips 25 separating the two partial apertures 23 , 24 is arranged at the point with the narrowest wall curvature. The respective angular distance of the maxima is therefore larger than in the case of a tube with a comparable cross-sectional area but a circular cross-section. The two electrode strips 13 , 14 are arranged on the outer wall in such a way that they face each other with a maximum stroke distance. The light coming from the two partial apertures 23 , 24 is coupled directly over the leading edge 26 of the light guide plate 27 into this.

Fig. 6 finally shows a schematic step illustration of an example of a flat lighting device 28 with a reflective optical system. The same features as in Fig. 3 are again provided with the same reference numerals. The optical system 29 is integrated in the region of the narrow side of the light guide plate 11 which is distant from the lamp. It consists of a slope 30 which extends over the entire length of the narrow side. The surface of the bevel 30 is provided with a layer 31 which reflects the lamp light. Slopes are suitable whose tilt angles ε to the perpendicular to the base of the light guide plate 11 satisfy the following relationship:

where α _G denotes the material-dependent angle of total reflection.

The invention is not restricted to the examples mentioned above. In particular Individual characteristics of the different examples can also be combined nation essential to the invention. Furthermore, it is also according to the invention, white tere optical elements, such as cylindrical lenses to reduce the Coupling losses in the light guide plate, with those mentioned in the examples to combine measures.  

Although the invention is for the sake of simplicity based on a rod-shaped Aperture lamp has been explained, the for the invention Be lamps suitable lamps can also be angled at for example L-shaped or U-shaped, in which case the light from the lamp over two or three edges is coupled into the light guide plate. The takes achievable luminance on the front of the light guide plate even more. In addition, the lighting device can also do more than one Have lamp, for example two, three or four, each of these Lamps into one of the lights by means of an associated optical system treads of the light guide plate couples light.

Claims (18)

1. Flat lighting device ( 8 ) with

• 1. a discharge lamp ( 9 ) with
  • 1. a tubular discharge vessel ( 12 ) which contains an ionizable filling in its interior,
  • 2. a phosphor layer ( 16 ) which at least partially covers a wall of the discharge vessel,
  • 3. a number of electrodes ( 13 , 14 ),
  • 4. an aperture ( 17 ) through which light passes during operation of the lamp ( 9 ),
• 2. an optical system ( 10 ; 29 ) which is suitable for spatially redistributing the light emitted by the phosphor layer ( 16 ),
• 3. a light guide plate ( 11 ) with
  • 1. a first narrow side ( 18 ) facing the lamp ( 9 ) and a second narrow side facing away from the lamp and
  • 2. a front,

wherein a solder defines an optical axis (A) on the tubular discharge vessel ( 9 ), which solder runs parallel to the front and centrally through the light guide plate ( 11 ), and the light from the lamp ( 9 ) through the first narrow side ( 18 ) into the light guide plate ( 11 ) and out through the front of the light guide plate ( 11 ), characterized in that the optical system ( 10 ; 29 ) the spatial light distribution of the light to be coupled in or coupled into the light guide plate ( 11 ) influences in such a way that, viewed in the cross-sectional plane of the lamp, the light distribution has at least a maximum angular distance β, measured with respect to the optical axis (A), the angular distance β fulfilling the following relationship:
where L is the longitudinal extent of the light guide plate ( 11 ) - ie its extent in the direction of the optical axis (A) - and d is its thickness. 2. Lighting device according to claim 1, wherein the number of Ma xima is two, in each case a maximum on both sides of the optical axis (A) at the angular distance β ₁ and β ₂ , the relationship ( 1 ) being fulfilled for both angles. 3. Lighting device according to claim 2, wherein | β ₁ | = | β ₂ |. 4. Lighting device according to one of the preceding claims, wherein the optical system either in the area of the first narrow side ( 18 ) as a transmissive element ( 10 ) or in the area of the second narrow side as a reflective element ( 29 ) in the light guide plate ( 11 ) is inte grated . 5. Lighting device according to claim 4, wherein the optical Sy stem ( 29 ) for generating a light distribution with a single Ma ximum is essentially realized in that a narrow side of the light guide plate ( 11 ) has a slope ( 30 ) with the tilt angle ε to the perpendicular the opposite side of the base of the light guide plate 11 . 6. Lighting device according to claim 5, wherein for the tilt angle ε the relationship
applies, where α _G denotes the material-dependent angle of total reflection. 7. Lighting device according to claim 4, wherein the optical system to produce a light distribution with two maxima essentially is realized in that a narrow side a V-shaped or pa raven-shaped neckline. 8. Lighting device according to claim 5, 6 or 7, wherein the second narrow side is provided with a reflection layer ( 31 ). 9. Lighting device according to one of claims 1 to 3, wherein the optical system is formed in that the aperture is divided in two such that the two elongated partial apertures ( 23 , 24 ) are arranged parallel to each other and through a narrow to the first narrow side ( 26 ) the light guide plate ( 21 ) parallel web ( 25 ) are separated from each other ge. 10. Lighting device according to claim 9, wherein the tubular discharge vessel has a drop-like cross section and where the web ( 25 ) separating the two partial apertures ( 23 , 24 ) is arranged at the point with the narrowest wall curvature and the two electrode strips ( 13 , 14 ) are arranged on the outer wall of the discharge vessel in such a way that they face each other with a maximum stroke distance. 11. Lighting device according to one of the preceding claims, wherein the width (b) of the aperture ( 17 ) corresponds approximately to the thickness (d) of the light guide plate ( 11 ). 12. Lighting device according to claim 11, wherein the ratio b / d from aperture width b to the thickness d of the light guide plate greater or equal 0.6, preferably greater than or equal to 0.8, particularly preferably greater than or is 1. 13. Lighting device according to one of the preceding claims, the optical system being one or more of the following contains: cylindrical lens, Fresnel foil, prism foil. 14. Lighting device according to one of the preceding claims, the lighting device additionally having an optical reflect gate that has at least the space between the aperture and the narrow surrounds the side of the light guide plate. 15. Lighting device according to one of the preceding claims, wherein the discharge lamp ( 9 ; 22 ) is suitable for operation by means of dielectric barrier discharge and for this purpose the electrodes ( 13 , 14 ) are arranged on the wall of the discharge vessel ( 12 ), wherein at least some of the electrodes are separated from the inside of the discharge vessel ( 12 ) by a dielectric ( 100 ). 16. Lighting device according to claim 15, wherein the number of electrodes ( 13 , 14 ) is two, wherein the electrodes ( 13 , 14 ) are strip-shaped and are arranged parallel to the longitudinal axis of the tube and diametrically to one another - ie at the maximum mutual distance. 17. Lighting device according to one of the preceding claims, wherein the largest diameter (w) of the tubular discharge vessel ( 12 ) is equal to or greater than the thickness (d) of the light guide plate ( 11 ). 18. Lighting device according to one of the preceding claims, the filling consisting of an inert gas, in particular xenon or a Mixture of several noble gases exists.