DE10140692A1 - Interior lighting unit for vehicle, using lamps of differing spectral emission, forms combined output using reflector and optical guide - Google Patents

Abstract

An optical guide (5) covers a reflector (3). A lamp (2a) associated with the reflector transmits light through the guide, to the reflector and back out again. At one end of the guide there is a light inlet (9) for a second lamp (2b). Its light follows the guide until an imperfection (10) acting as an optical exit is reached. Reflector and guide geometry ensure that light from both lamps leaves in approximately the same direction

Description

The invention relates to a lighting device for vehicles, in particular an interior lamp, with at least a first and at least one spaced-apart second illuminant, the light emit with different spectral distribution, and with one Reflector for focusing the light.

A lighting device is already known from EP 0 416 253 B1 of the type mentioned, which has a reflector, the extends in a surface that is rotated by a parabola or elliptical section is formed about an axis of rotation. the To generate white light, reflectors are several red and green ones and assigned blue LEDs that cover the scope of the Reflector are arranged distributed, in each case in the focal point or on the focal line of the reflector. The lighting device has the disadvantage of producing a large number of white light of staggered on the circumference of the reflector LEDs is needed, which is why the lighting device is correspondingly complex and expensive. In addition, those of the different light sources only emit light beams mixed relatively poorly, which Color inhomogeneities of the light emitted by the lighting device may occur. It is also unfavorable that the Lighting device still has comparatively large dimensions.

There is therefore the task of a lighting device to create the light with a desired Light color emits, but still a compact, simple and enables inexpensive construction.

The solution to this problem is that the first lamp is assigned to the reflector that in the radiation area of the reflector a transilluminated by the light reflected by the reflector Light guide is arranged, the end face at least one has light entry surface assigned to second illuminant, that the light guide at least one point of interference for decoupling of light of the second illuminant guided in the light guide has at a light exit point of the light guide, and that the reflector and the light guide are designed such that the light exit of this light from the second illuminant, for example in the same direction as the light emission from light of the first illuminant, which at the same light exit point or a neighboring point emerges from the light guide.

So the reflector is connected in series with a light guide, which is arranged behind the reflector in the direction of radiation is, so that the light reflected from the reflector of the first Illuminated the light guide and at that the Front of the reflector facing away from the light guide. That on the front light coupling surface in the light guide Coupled light from the second illuminant is through Total reflection in the light guide until it hits one in Impact point provided at the light guide, where it is so is deflected that it is at the front of the light pipe located light exit surface emerges from the light guide and then mixes with the light from the first illuminant. Those emerging from the light guide at the front Light rays from the second illuminant each run to it coaxial or closely adjacent light rays of the second Illuminant roughly parallel, creating a good additive mixture of the light having the different spectral distribution of the individual illuminants is made possible. Through the Series connection of the reflector with the light guide results in a compact, easy and inexpensive to manufacture Lighting device, which emits light with a desired light color enables.

It is advantageous if the reflector and the light guide for Bundling the light of the illuminants into a bundle of light with approximately parallel light rays are formed. The light from the different illuminants can then be even better can be mixed to a desired light color.

In a preferred embodiment of the invention, that at least a portion of the reflective surface of the reflector rotationally symmetrical with respect to one through the emission point of the is formed first axis of rotation extending axis of rotation and that this part of the reflection surface in radial planes, which contain this axis of rotation, taking into account the Shape and the refractive index of the light guide so arcuate with outward curvature that is curved in these Radial planes of the illuminant assigned to the reflector emitted light is deflected on the reflector such that its direction of radiation after emerging from the light guide runs parallel to the axis of rotation. The reflector is then on easy to manufacture. Because of the one hand when entering of the light emitted by the first illuminant in the Light guide and on the other hand when this light emerges light refraction occurring on the outer surface of the light guide the reflection surface of the reflector has one of the outer surface a paraboloid of revolution or an ellipsoid of revolution deviating shape on the light of the first illuminant bundles so that the light rays reflected at the reflector after passing through the light guide approximately parallel to each other run.

In a particularly advantageous embodiment of the invention it is provided that the at least one first illuminant the front and the reflector on the back of the light guide is arranged and that the reflector is preferably a coating is applied to the back of the light guide. The light guide then preferably consists of a crystal clear Plastic material on which the reflector is evaporated. The light guide then fulfills a double function and serves, in addition to leading the Light of the second illuminant from the light entry surface to the light exit surface also as a support part for the reflector. The light guide can be inexpensive as a plastic injection molded part getting produced. Because the reflector is a thin coating can be formed, enables the lighting device correspondingly compact dimensions.

In an expedient embodiment of the invention that is at least one first lamp as essentially white Light-emitting light-emitting diode and the at least one second illuminant is designed to emit red light. As a result, the high typical for "white" LEDs Color temperature can be reduced or the bluish tending light color of the "white" light emitting diode can in one warm shade can be compensated for, especially in a Lighting device designed as a vehicle interior light by the users of the lighting device as pleasant is felt. Because of the in the light of Illuminating device contained red component is particularly suitable for Illumination of a make-up toy gel, with good color rendering is achieved. The second illuminant assigned to the light guide can be a red light-emitting diode or an electroluminescent film exhibit.

In an advantageous embodiment of the invention provided that at least one, preferably on the back the light guide arranged impurity by a projection or a depression is formed that has a surface area has, which opposite to the projection or the recess adjacent surface area for coupling out a light beam or light beam is inclined from the light guide. At least a fault can then be the same when the light guide is injection molded be molded onto this. It is even possible to do one Arrange a large number of impurities over the reflector. The defects can be at regular intervals be arranged, for example in a matrix in rows and columns. But it is also possible to locate the imperfections in irregular To arrange distances, for example according to one Random function of a uniformly over the reflective surface of the Reflectors distributed regular patterns deviating. Thereby can make moiré patterns on one with the lighting device illuminated target area can be avoided.

At least one protrusion or depression can be prismatic be formed, which is uniform over the reflecting surface Coupling out light of the second illuminant from the light guide allows.

But it is also conceivable that at least one lead ledge-shaped and / or at least one recess formed groove-shaped and is preferably on a circular arc one in one normal to the axis of rotation of the partial area of the reflection surface of the reflector plane concentric with the Rotation axis extending circle extends. The light guide is then easily removable from the injection mold as a plastic injection molded part.

It is advantageous if the lamps are on a common Printed circuit board are arranged, preferably with their Extension plane approximately parallel to the axis of rotation of the Part of the reflection surface of the reflector extends. The Lighting device is then simple to manufacture Can be assembled in this way. On the circuit board, if necessary a control circuit for the lamps can be accommodated. The circuit board can be used for connecting to the Have reflector.

In a particularly advantageous embodiment of the invention it is provided that in the beam path of the reflector emitted light beam in the direction of radiation behind the Light guide an optical disc having optical scattering elements and / or a deflection mirror having optical scattering elements is arranged. This can be a particularly uniform Mixing of different illuminants emitted light and thus one over the entire with the Illumination device homogeneous target surface to be illuminated Light color can be achieved.

Below are exemplary embodiments of the invention based on the Drawings explained in more detail. Show it:

Fig. 1 shows a section through a longitudinal central plane of an illumination device that, with only the portions of the illumination device situated in the longitudinal median plane are shown and wherein a dashed line light rays are indicated a reflector and a series geschaltenen light guide and a light disc with this

Similar to FIG. 2, an illumination device Fig. 1, but wherein a deflection mirror is provided in place of the lens,

Fig. 3 is a plan view in Fig. 1 denoted by III plane of the illumination device,

Fig. 4 is a perspective view of the lighting device shown in Fig. 3, the individual parts of the illumination device are shown transparent for clarity,

Fig. 5 is a plan view of the inside of the reflector of an illuminating device, wherein the contour of the Reflektors- is indicated by contour lines and auxiliary

FIG. 6 is a perspective view of the lighting device shown in FIG. 5, the individual parts of the lighting device being shown transparently and the contour of the reflector being illustrated by contour auxiliary lines.

A lighting device, designated as a whole as 1 and designed as a vehicle interior light, has two spaced-apart illuminants 2 a, 2 b, which emit light with a different spectral distribution. In Figs. 1 and 2 is seen that the lamps 2 a, 2 b are arranged in the location indicated by the arrow Pf1 main emission direction of the illumination device 1 in succession.

The first illuminant 2 a, which is at the front in the main emission direction Pf 1 of the illuminating device 1 , is designed as a “white” light-emitting diode that emits light whose spectral distribution - apart from a missing red component - corresponds approximately to that of white light. The second illuminant 2 b, which is at the rear in the main emission direction Pf 1 of the illuminating device 1, is designed as a red light-emitting diode which emits in a spectral range which corresponds approximately to the missing red component of the first illuminant 2 a.

To bundle the light from the first illuminant 2 a, a reflector 3 is assigned to this illuminant 2 a, which is arranged with its reflection surface 4 in the radiation area of the first illuminant 2 a.

Pf1 in the main direction of the illumination device behind the reflector 3 in the emission of the reflector 3, a light guide 5 is arranged, which is illuminated by the light emitted by the reflector 3 light beams. In Figs. 1 and 2 it is seen that the light source 2a is disposed on the opposite side of the reflector 3 of the optical fiber 5. It illuminated by a Abstrahlstelle 6, a divergent light beam from that at the reflector 3 side facing away from the optical fiber 5 entering therein and is deflected upon impact with the reflector 3 such that it on the side remote from the reflector side of the light guide 5 again from this exit. Thereby the broken in Fig. 1 and 2 by dashed lines indicated light beams 7 a of the light beam forward both when entering and respectively on the side remote from the reflector 3 at the exit from the light guide 5, in the emission Pf1 facing lateral surface 8 of the optical fiber 5.

The light guide 5 has a light entry surface 9 on one end face, which faces the second illuminant 2 b. This emits a divergent light beam that enters the light guide 5 at the light entry surface 9 . On the walls of the light guide 5 , the light of the second illuminant 2 b is subject to total reflection.

The light guide 5 has defects 10 for coupling out the light of the second illuminant 2 b guided in the light guide 5 . Some of the defects 10 are arranged on the opposite side of the light guide 5 from the radiation side of the light guide 5 and are each configured such that the light of the second illuminant 2 b striking them is deflected such that it is on the front of the light guide 5 opposite the defect 10 exits at a light exit point 11 located there. At this light exit point 11 , a further fault point 10 can be arranged, as can be seen in FIGS. 1 and 2 in the upper half of the light guide 5 .

The reflector 3 and the light guide 5 are designed such that the light exit of the light of the second illuminant 2 b takes place approximately in the same direction as the light exit of the light of the first illuminant 2 a, which light at the same light exit point 11 or one immediately adjacent thereto Place emerges from the light guide 5 . In Figs. 1 and 2 is clearly seen that the light beams 7 a of the first lighting means 2 a and the light rays 7 b of the second light-emitting means 2 b is about parallel to each other after emerging from the optical fiber 5. Thus, the light of the first illuminant 2 a and the light of the second illuminant 2 b are additively mixed with one another, that is to say the red component missing from the light of the illuminant 2 a designed as a “white” light-emitting diode is at least replaced by the red light of the second illuminant 2 b partially compensated, whereby a desired light color is achieved.

The reflector 3 is designed in consideration of the refraction of light at the light guide 5 such that the light reflected at the reflector 3, extending from the first light emitting means 2 a radiated light beams after exit from the light guide 5 approximately parallel to each other. For this purpose, the subareas of the reflection surface 4 of the reflector 3 , on which no defects 10 are arranged, are rotationally symmetrical with respect to an axis of rotation 12 running through the virtual emission point 6 of the first illuminant 2 a. Under the virtual Abstrahlstelle 6 is meant a site, of the luminous means 2 a located observer are apparently radiated from the group consisting of the first light emitting means 2 a radiated light beams 7a for effecting in light emission behind a light refraction light exit surface. 13

The subareas of the reflecting surface 4 of the reflector 3 , at which no impurities 10 are arranged, are in an arc-shaped manner in a radial plane containing the axis of rotation 12 and corresponding to the plane of the drawing in FIGS. 1 and 2, taking into account the shape and the refractive index of the light guide 5 decreasing curvature curved to be from the reflector 3 associated lamps 2 a radiated light beam 7 a so at the reflector 3 is deflected in the radial plane, that their direction of radiation runs approximately after exiting from the light guide 5 parallel to the rotational axis 12th

In Figs. 1 and 2 it can be seen that the reflector 3 on the emission side of the light guide is applied 5 opposite rear side of the optical fiber 5 as a coating. The reflector material is preferably vapor-deposited on the back of the light guide 5, which is made of a clear plastic material.

Some defects 10 are formed by depressions located on the back of the light guide 5 and at least one further defect 10 is formed by a projection located on the front of the light guide 5 . The defects 10 each have at least one surface area that is inclined in a radial plane containing the axis of rotation 12 and passing through the defects 10 with respect to a surface area of the light guide 5 that is adjacent to the relevant defect 10 .

In the embodiment according to Fig. 3 and 4, the impurity 10 formed as a protrusion are strip-shaped and the impurity 10 formed as a depression designed groove-like. In this case, these impurities 10 each extending arcuately along a circular line of a concentrically arranged in a normal to the axis of rotation 12 plane to the rotation axis 12 imaginary circle.

As can be seen particularly well in FIGS. 1 and 2, the illuminants 2 a, 2 b are arranged on a common printed circuit board 14 which extends parallel to the axis of rotation 12 with its plane of extension.

In the exemplary embodiment according to FIG. 1, an optical lens 15 is arranged in the beam path of the light beam emitted by the reflector 3 in the radiation direction behind the light guide 5 and has optical scattering elements 16 for scattering the light impinging thereon from both lamps 2 a, 2 b. In Fig. 1 on the right it can be seen that the light beams 7 a, 7 b emitted by the individual illuminants 2 a, 2 b are scattered on the scattering elements 15 in light beams which overlap one another. As a result, a uniform light color is achieved over the entire target surface to be illuminated with the light from the lighting device 1 .

In the exemplary embodiment according to FIG. 2, a deflection mirror 17 is arranged in the beam path of the light beam emitted by the reflector 3 in the radiation direction behind the light guide 5 and has optical scattering elements 18 for scattering the light from both lamps 2 a, 2 b. On the right in FIG. 2 it can be seen that the light beams 7 a, 7 b emitted by the individual illuminants 2 a, 2 b are scattered and deflected at the scattering elements 18 into mutually overlapping light beams. Thus, here too, a uniform light color results over the entire target surface to be illuminated with the light of the lighting device 1 .

The lighting device 1 for vehicles, which is designed in particular as an interior light, thus has at least one first and at least one second light means 2 a, 2 b spaced therefrom, which emit light with different spectral distribution. The first illuminant 2 a is assigned to a reflector 3 for bundling the light. Arranged in the radiation area of the reflector 3 is a light guide 5 which is illuminated by the light reflected by the reflector 3 and has at the end face at least one light entry surface 9 assigned to the second illuminant 2 b. The light guide 5 has at least one fault point 10 for coupling out light of the second illuminant 2 b guided in the light guide 5 at a light exit point 11 of the light guide 5 . The reflector 3 and the light guide 5 are designed such that the light exit of this light of the second illuminant 2 b from the light guide 5 takes place approximately in the same direction as the light exit of light of the first illuminant 2 a from the light guide 5 , which light at the same light exit point 11 or an adjacent location emerges from the light guide 5 .

Claims (10)

1. Lighting device ( 1 ) for vehicles, in particular interior lights, with at least one first and at least one second light means ( 2 a, 2 b) spaced therefrom, which emit light with different spectral distribution, and with a reflector ( 3 ) for focusing the light, characterized in that the first illuminant ( 2 a) is assigned to the reflector ( 3 ), that in the radiation area of the reflector ( 3 ) there is a light guide ( 5 ) which is transilluminated by the light reflected by the reflector ( 3 ) and has at least one end face The light entry surface ( 9 ) assigned to the second illuminant ( 2 b) has that the light guide ( 5 ) has at least one defect ( 10 ) for coupling out light of the second illuminant ( 2 b) guided in the light guide ( 5 ) at a light exit point ( 11 ) of the light guide ( 5 ), and that the reflector ( 3 ) and the light guide ( 5 ) are designed such that the light exit of this light of the second illuminant ( 2 b) takes place approximately in the same direction as the light exit of light from the first illuminant ( 2 a), which emerges from the light guide ( 5 ) at the same light exit point ( 11 ) or at a point adjacent thereto. 2. Lighting device ( 1 ) according to claim 1, characterized in that the reflector ( 3 ) and the light guide ( 5 ) for bundling the light of the lamps ( 2 a, 2 b) in a light bundle with approximately mutually parallel light beams ( 7 a , 7 b) is formed. 3. Lighting device ( 1 ) according to claim 1 or 2, characterized in that at least a portion of the reflection surface ( 4 ) of the reflector ( 3 ) is rotationally symmetrical with respect to a through the radiation point ( 6 ) of the first lamp ( 2 a) extending axis of rotation ( 12 ) is formed and that this portion of the reflecting surface ( 4 ) in radial planes which contain this axis of rotation ( 12 ), taking into account the shape and refractive index of the light guide ( 5 ), is curved in an arcuate manner with an outwardly decreasing curvature such that in these radial planes of the reflector (3) associated with the luminous means (2 a) is diverted light emitted in such a way to the reflector (3) that its direction of radiation runs approximately after exiting from the light guide (5) parallel to the axis of rotation (12). 4. Lighting device ( 1 ) according to one of claims 1 to 3, characterized in that the at least one first illuminant ( 2 a) on the front and the reflector ( 3 ) on the back of the light guide ( 5 ) is arranged and that the reflector ( 3 ) is preferably applied as a coating to the back of the light guide ( 5 ). 5. Lighting device ( 1 ) according to one of claims 1 to 4, characterized in that the at least one first illuminant ( 2 a) is designed as a substantially white light-emitting light-emitting diode and that the at least one second illuminant ( 2 b) for emitting red light is formed. 6. Lighting device ( 1 ) according to one of claims 1 to 5, characterized in that the at least one, preferably on the back of the light guide ( 5 ) arranged defect ( 10 ) is formed by a projection or a recess which has a surface area, which is inclined relative to a surface area adjacent to the projection or the depression for coupling out a light beam or light bundle from the light guide ( 5 ). 7. Lighting device ( 1 ) according to one of claims 1 to 6, characterized in that at least one projection or a recess is prism-shaped. 8. Lighting device ( 1 ) according to one of claims 1 to 7, characterized in that at least one projection is strip-shaped and / or at least one recess is groove-shaped and is preferably on a circular arc in a normal to the axis of rotation ( 12 ) of the portion of the reflection surface ( 4 ) of the reflector ( 3 ) extending plane concentric to the axis of rotation ( 12 ) extending circle. 9. Lighting device ( 1 ) according to one of claims 1 to 8, characterized in that the lamps ( 2 a, 2 b) are arranged on a common printed circuit board ( 14 ), preferably with its plane of extension approximately parallel to the axis of rotation ( 12 ) of the Part of the reflection surface ( 4 ) of the reflector ( 3 ) runs. 10. Lighting device ( 1 ) according to one of claims 1 to 9, characterized in that in the beam path of the light beam emitted by the reflector ( 3 ) in the radiation direction behind the light guide ( 5 ) an optical scattering elements ( 16 ) having lens ( 15 ) and / or a deflecting mirror ( 17 ) having optical scattering elements ( 18 ) is arranged.