Lighting device for vehicles

Abstract

A lighting device for vehicles with a first lighting unit having a light source and a light beam surface for emitting light and with a second lighting unit containing a light source and a flat light guide having opposite flat sides and narrow sides connecting the same for backlighting the first lighting unit. The flat light guide of the second lighting unit has a backlighting section and a linear light section. The backlighting section is arranged behind the first lighting unit and a front flat side of the flat light guide in the backlighting section serves as a light decoupling surface for the light decoupling of a first part of the light coupled into the flat light guide. The linear light section is at least partially arranged next to the first lighting unit. A narrow side of the flat light guide serves as a light decoupling line.

Claims

1. A lighting device for a vehicle, the lighting device comprising: a first lighting unit having a light source and a light beam surface for emitting light; and a second lighting unit having a light source and a flat light guide having opposite flat sides and same connecting narrow sides for backlighting the first lighting unit, wherein the flat light guide of the second lighting unit has a backlighting section and a linear light section adjoining the backlighting section, wherein the backlighting section is arranged behind the first lighting unit, wherein a front flat side of the flat light guide in the backlighting section serves as a light decoupling surface for the light decoupling of a first part of the light coupled into the flat light guide, wherein the linear light section is arranged at least partially next to the first lighting unit, and wherein a narrow side of the flat light guide in the linear light section serves as a light decoupling line for the light decoupling of a second part of the light coupled into the flat light guide.

2. The lighting device according to claim 1, wherein an aperture is arranged between the first lighting unit and the second lighting unit with partially transparent and/or transparent areas for illuminating the first part of the light according to a given shape pattern.

3. The lighting device according to claim 1, wherein the light beam surface of the first lighting unit is formed as a liquid crystal field having a plurality of individually electronically controllable liquid crystal pixels or liquid crystal segments.

4. The lighting device according to claim 1, wherein the light beam surface of the first lighting unit has a flat light guide with opposite flat sides and a narrow side connecting them, wherein a light source is arranged on at least one of the narrow sides for coupling light into the flat light guide and wherein rear and/or front decoupling elements are assigned to the flat light guide, so that the coupled light can be decoupled on a front flat side of the flat light guide, and that further optical foils or optical discs can be upstream of the flat light guide.

5. The lighting device according to claim 1, wherein several equally designed first lighting units are located upstream of the backlighting section of the second lighting unit.

6. The lighting device according to claim 1, wherein the first lighting unit runs substantially parallel to the backlighting section of the second lighting unit.

7. The lighting device according to claim 1, wherein a light source of the first lighting unit and a light source of the second lighting unit are arranged on a common printed circuit board arranged on one side of the flat light guide opposite the linear light section.

8. The lighting device according to claim 1, wherein the flat light guide of the second lighting unit if formed of a flexible material with a plurality of recesses accommodating the light sources.

9. The lighting device according to claim 8, wherein the backlighting section of the flat light guide has reflective elements on the rear flat side for reflecting the coupled light and, on a front flat side, has, at least partly, optical elements for scattering the decoupled light.

10. The lighting device according to claim 9, wherein the optical elements arranged on the front flat side are arranged in a region through which an optical axis of the light source assigned to it passes.

11. The lighting device according to claim 9, wherein the reflective elements and/or optical elements are produced by printing and/or by structuring in the ?m range.

12. The lighting device according to claim 1, wherein the reflective elements are arranged on the rear flat side of the backlighting section over the entire rear flat side, avoiding the recesses.

13. The lighting device according to claim 1, wherein the light sources are arranged equally distributed on the rear flat side of the backlighting section.

14. The lighting device according to claim 1, wherein the light sources of the first lighting unit and the second lighting unit are designed as LED light sources of a given color or as RGB LED light sources.

15. The lighting device according to claim 1, wherein the first and second lighting units are provided for generating an identical, common signal light function or different signal functions.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The present invention will become more fully understood from the detailed description given hereinbelow and the accompanying drawings which are given by way of illustration only, and thus, are not limitive of the present invention, and wherein:

(2) FIG. 1 shows a perspective front view of a lighting device,

(3) FIG. 2 shows a perspective partial front view of the lighting device,

(4) FIG. 3 shows an illumination of the lighting device with a light signature of a first lighting unit according to an example,

(5) FIG. 4 shows an illumination of the lighting device with a light signature of the first lighting unit according to an example,

(6) FIG. 5 shows a perspective front view of the lighting device containing an aperture between the first lighting unit and the second lighting unit,

(7) FIG. 6 shows a vertical cross-section through the lighting device,

(8) FIG. 7 shows a vertical cross-section through the lighting device with an example of the rear second lighting unit,

(9) FIG. 8 shows a representation of light rays within a backlighting section of the flat light guide of the second lighting unit, and

(10) FIG. 9 shows a front view of the backlighting section as shown in FIG. 8.

DETAILED DESCRIPTION

(11) For example, a lighting device for vehicles can serve as a rear light for generating tail, brake and direction indicator lights. In FIG. 1, a lighting device is designed as a rear light with a housing 1 in which a first lighting unit 2 and a second lighting unit 3 are arranged. The first lighting unit 2 is arranged in the main beam direction H in front of the second lighting unit 3.

(12) The housing 1 is pot-shaped with an opening on the front. The front opening is closed by a light-transparent lens, which is not shown.

(13) The front first lighting unit 2 has a number of light sources 4 and a light beam surface 5, which is formed as a liquid crystal field with a plurality of individually electrically controllable liquid crystal pixels or liquid crystal segments.

(14) The rear second lighting unit 3 has a number of light sources 6 as well as a flat light guide 7, which has opposite flat sides 8, 9 and the same connecting narrow sides 10. As can be seen better from FIGS. 5 and 6, the flat light guide 7 of the second lighting unit 3 has a backlighting section 11 and a linear lighting section 12, which is directly adjacent to the backlighting section 11. The backlighting section 11 and the linear lighting section 12 are connected to each other in one piece. The backlighting section 11 is located behind the light beam surface 5 of the first lighting unit 2. The linear light section 12 is arranged next to the light beam surface 5 of the first lighting unit 2.

(15) In the backlighting section 11, a front flat side 8 of the flat light guide 7 is designed as a light decoupling surface, from which a first part 14 of a light 25 coupled into the flat light guide 7 is decoupled in the direction of the light beam surface 5 of the first lighting unit 2. For this purpose, the flat light guide 7 has 9 decoupling elements 13 in the backlighting section 11 on the rear flat side. The decoupling elements 13 can be produced, for example, by printing or by structuring. The dimensioning of the decoupling elements 13 is in the ?m range.

(16) In the linear lighting section 12, the rear flat side 9 has no decoupling elements. In this case, there is only a total reflection of the coupled light 25 in the direction of a narrow side 10, which serves as a light decoupling line for the decoupling of a second part 15 of the light 25 of the light source 6 coupled at an opposite light-coupling narrow side 10.

(17) As can be seen from FIG. 3, the liquid crystal pixels of the first lighting unit 2 can be controlled in such a way that a first light signature 16 is generated with illuminated diamonds 17 and a light line 18 generated by the second lighting unit 3. The light beam surface 5 of the first lighting unit 2 is formed of several triangular segments 19 (liquid crystal segments), each of which is assigned a liquid crystal pixel. In the first light signature 16, liquid crystal pixels associated with the adjacent illuminated segments 19 are turned on while the others are turned off. The first light signature 16 may be used to produce a signal light function or to produce a decorative light function. For example, the elongated light line 18 can be used to generate a taillight function.

(18) According to an example of the invention according to FIG. 4, the first lighting unit 2 may produce a second light signature 20 composed of a plurality of arrowheads 26 touching each other at one point. These are controlled by segments 19 connected by corner edges. This results in a different geometry of the light signature.

(19) As can be seen from FIG. 1 and FIG. 5, the flat light guide 7 of the second lighting unit 3 engages behind several identically designed first lighting units 2. The light sources 4, 6 of the first lighting unit 2 and the second lighting unit 3 are arranged on a common printed circuit board 21. The lighting device can therefore be relatively space-saving and simple.

(20) For example, an aperture 22 can be arranged between the first lighting unit 2 and the second lighting unit 3, which preferably has partially transparent and/or transparent areas for illumination of a given shape pattern applied to the aperture 22. The backlighting by means of the backlighting section 11 of the second lighting unit 3 can thus be provided with a predefined pattern. For example, the aperture 22 may be made of a transparent disc provided with vaporized and/or painted surfaces. By means of a subsequent laser application process, the areas are lasered free to form the transparent areas of the aperture 22. The other areas remain opaque or partially transparent, so that a specific shape pattern can be created.

(21) The shape pattern of the aperture 22 may also be provided by a printed film laminated or glued to a transparent disc. Alternatively, the printed film may be applied directly to the front flat side 8 of the backlighting section 11, in particular laminated and glued. Alternatively, the aperture 22 can also be designed as an opaque injection molded component with, for example, a lattice-like mold structure.

(22) As can be seen from FIG. 6, in order to deflect the light coming from the backlighting section 11, the linear light section 12 may have planar sections 23 on the front flat side 8 and planar sections 24 on the rear flat side 9. Alternatively, the light deflection section for deflection of the light guidance by 90? can also be arc-shaped.

(23) According to FIG. 7, an alternative second lighting unit 3 can be provided comprising a flexible flat light guide 27 with opposite front flat sides 28 and a rear flat side 29. The flat light guide 27 has a backlighting section 30 and an arc-shaped linear light section 31, each of which has the same function as the corresponding sections 11, 12 of the second lighting unit 3. The rear flat side 29 can have recesses 32 in the backlighting section 30, in each of which the light sources 6 are arranged. The light sources 6 are preferably designed as LED light sources, which are preferably encapsulated with a transparent silicone material to form the backlighting section 30. The light sources 6 are connected to each other by thin wires, not shown, and are contacted with an unshown laterally arranged connector.

(24) Preferably, the flat light guide 7 has 29 reflective elements 33 on the rear flat side in the backlighting section 30 and 28 optical elements 34 on the front flat side. This can be done, for example, by appropriate printing. Alternatively, this can also be done by structuring the surface of the front flat side 28 and/or the rear flat side 29. The reflection elements 33 serve as decoupling elements and cause a reflection of the coupled light, wherein example beams L1 are shown in FIG. 8. The optical elements 34 are arranged in a region 35 of the front flat side 28 in which an optical axis A of the light sources 6 extends. Preferably, the region 35 is arranged circularly and/or coaxially to the respective light sources 6. In this way, a scattering of the light directly irradiated by the light sources 6 is caused, which has a homogenizing effect or avoids a light concentration, see example light rays L2 in FIG. 8.

(25) The dimensioning of the reflective elements 33 and the optical elements 34 is in the ?m range.

(26) The light sources 6 can be designed as LED light sources, in particular as RGB light sources, so that different light colors are generated over the area of the backlighting section 30. Alternatively, monochrome LED light sources can also be provided, wherein these emit different light colors. In this way, a specific color pattern can be created or a multi-colored light staging in conjunction with the first lighting unit 2.

(27) Further, the light sources 6 of the backlighting section 30 may also emit the same light color.

(28) If the light sources 6 are designed as RGB LED light sources, they can provide a colored backlighting in an initial operating state in which the first lighting unit 2 produces a first light signature function, for example, a welcome light function. In a second operating state, in which, for example, the first lighting unit 2 is switched off, the light sources 6 of the second lighting unit 3 may be switched in such a way that they emit a red light color to generate the signal light function taillight or brake light.

(29) In the regions 35, for example, the printing can be designed as a white dot grid whose dot size and spacing are different. Alternatively, the printing can also have other grid patterns, such as lines, triangles, rectangles, polygons or other geometric shapes. Alternatively, the region 35 can also be provided with a paint of specified residual transmission over the entire surface. The reflective elements 33 are preferably produced by printing, preferably by a white printing, which has a diffuse reflective effect on the coupled light. Preferably, the entire rear flat side 29 in the backlighting section 30, with the exception of the recesses 32, is provided with the reflective element printing.

(30) The backlighting sections may run parallel to the light beam surface 5 of the second lighting unit 3.

(31) Further, the first lighting unit 2 may also be formed by a flat light guide, which corresponds in function and structure to the backlighting section 30 of the second lighting unit 3. The flat light guide has opposite flat sides and a number of narrow sides connecting the same, wherein a light source is arranged on at least one of the narrow sides for light coupling into the flat light guide and wherein rear and/or front decoupling elements are assigned to the flat light guide, so that the coupled light can be decoupled on a front flat side of the flat light guide, and that preferably the flat light guide is connected to other optical foils. or optical discs.

(32) The first and second lighting units 3, 3 may be provided to produce the same, common signal light function or different signal functions.

(33) The invention being thus described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are to be included within the scope of the following claims.