DE102013103410A1 - Lighting device for vehicles - Google Patents

Abstract

The invention relates to a lighting device for vehicles with a first light unit comprising a laser light source and a first optical unit associated with the laser light source, wherein a second light unit comprising an LED light source and a second optical device associated therewith is provided, wherein a footprint of the first optical device is greater than one Illuminated surface of the second optical device.

Description

The invention relates to a lighting device for vehicles with a first light unit comprising a laser light source and a first optical unit associated with the laser light source.

From the DE 197 46 025 B4 a lighting device for vehicles with a laser light source and an optical device for generating a predetermined light distribution is known. The laser light source is located remotely from the light exit point. The optical device comprises, on the one hand, a light guide and, on the other hand, a planar light output element, which is coupled via the light guide to the laser light source remote from the location. The known lighting device enables the generation of a light distribution by means of a laser light source. A disadvantage of the known lighting device is that it requires a relatively high installation and development effort, as well as a coordination of the optical components to each other and is associated with high costs.

Object of the present invention is therefore to develop a lighting device for vehicles such that laser light can be used for signal light functions in an economical manner.

To achieve this object, the invention in conjunction with the preamble of claim 1, characterized in that a second light unit comprising an LED light source and a second optical device associated therewith is provided, wherein a footprint of the first optical device is larger than a footprint of the second optical device ,

Advantageously, this makes it possible to use an expensive laser light source in an illumination device in combination with a low-cost LED light source in order to use the laser light for significant illumination or illumination of the signal function and additionally to generate the required light intensities for the signal function with the LED light source.

According to the invention, a local connection of a first lighting unit, which has a laser light source as a light source, with a second light unit, which has a LED light source as a light source, in a common housing. The two lighting units form a common structural unit, which is arranged compactly integrated in a housing of the lighting device. The different light source types allow a different lighting effect, which allows for improved perception and faster recognition, which is conducive to traffic safety. An illuminating surface of the lighting unit operated with the laser light source is selected to be larger than an illuminating surface of the lighting unit operated with the LED light source, wherein the actual signal function or light distribution is generated essentially by the lighting unit operated with the LED light source.

According to a development of the invention, the laser light source associated with the first optical device is designed as a surface light guide, on the narrow sides of the laser light source is arranged and in which the laser light is coupled. The coupled-in laser light is totally reflected by deflection means arranged on the narrow sides, so that the laser light beam travels a longer distance within the surface light guide than the surface light guide is formed wide or long. In this way, individual laser light beams, which roam around within the surface light guide, are advantageously recognizable to a viewer from the outside, so that a laser light beam pattern is formed. It is possible to generate a defined laser appearance, which draws the attention of other road users to the signal function of the lighting device. In this way, for example, a brake or flashing light can be perceived even safer than what is possible by the powered with the LED light source second light unit.

According to a development of the invention, the surface light guide is not made of a crystal-clear material, but of a material having such a degree of diffusion that the laser light beam running in this surface light guide can be seen from the outside. Advantageously, a material-related parameter of the surface light guide is set here in such a way that the laser light beam traveling around in the surface light guide is clearly recognizable as a beam / line.

According to a preferred embodiment of the invention, totally reflecting deflecting means are arranged on or in the planar light guide and / or the planar light guide is shaped such that a predefined laser light beam pattern can be recognized via the illuminating surface of the planar light guide. For example, a specific laser light line pattern can be generated with only a single laser beam, wherein, for example, the laser beam is totally reflected back and forth between the narrow sides. The path length of the laser beam traveled in the surface light guide can amount to a multiple of the width or length of the surface light guide. By coupling a plurality of laser light beams, the density of the group of lines within the surface light guide can be further increased. Optionally, a flat laser light pattern can be generated. The planar pattern produces a blasting of area light in the main emission direction, which can be used, for example, to generate a taillight or position light function.

According to a development of the invention, the laser light source can be assigned a beam splitter, so that the laser light beam can also be fanned out into a plurality of partial laser light beams. As a result, further different laser light beam patterns can be generated.

According to a development of the invention, the illuminating surface of the first optical device is at least three times as large as the illuminating surface of the second optical device. The laser light-based first light unit can thus be designed relatively flat and cover areas of the housing over a large area, which have a small overall depth. Due to the relatively large illumination area of the first lighting unit, individual laser light beams that propagate transversely to the main emission direction can be detected relatively well.

According to a development of the invention, the second lighting unit is arranged in the main emission direction before and / or integrated in the first lighting unit, so that a compact and space-saving arrangement is provided.

The color of the laser light, for example, dark red, and the color of the LED light may be in the same color range or wavelength range to form a uniform, colorful appearance, or the color of the LED light may be different from the laser light in a different wavelength range lie, for example orange-red to form a different colored appearance.

Embodiments of the invention are explained below with reference to the drawings.

Show it:

1 a schematic front view of a lighting device according to a first embodiment,

2 a schematic plan view of a lighting device according to a second embodiment,

3 a schematic plan view of a lighting device according to a third embodiment,

4 a schematic plan view of a lighting device according to a fourth embodiment and

5 a schematic plan view of a lighting device according to a fifth embodiment.

A lighting device according to the invention can be integrated in a headlight or in a tail light of a motor vehicle. Alternatively, the lighting device can also be used in or outside buildings.

The lighting device consists of two subsystems, wherein a first light unit 1 at least one laser light source 2 as a light source and a first optical device 3 having. As a second subsystem is a second light unit 4 provided that as a light source an LED light source 5 and a second optical device 6 having.

The LED light source 5 is formed as a light-emitting diode, which emits light when flowing an electric current in the forward direction. The light is emitted in a limited spectral range, for example as red, yellow or white light.

The laser light source 2 is designed as a laser diode, in which a pn junction is operated with high doping at high current densities. The laser diode has an optical resonator in which a standing light source is formed. The usable radiation is coupled out of the radiation field of the resonator, for example by partially reflecting mirrors. Preferably, a population inversion is present, so that a stimulated emission is produced in which laser light of a specific frequency, phase and polarization is emitted. The frequency of the laser light depends on the semiconductor material used.

The second light unit 4 has in the embodiment according to 1 as a second optical device 6 a rod-shaped light guide on the front side 7 the LED light source 5 is arranged. That at the front 7 coupled light is applied to lateral surfaces 8th of the light guide 6 totally reflected. On a rear side in the main emission direction H of the light guide 6 Auskoppelelemente are arranged by means of which they incident light in the direction of a front lateral surface 8th' is deflected so that it exits at the same in the main emission direction H. As a result, a high-intensity light function, such as, for example, brake light, flashing light or daytime running light function can be generated. The front lateral surface 8th thus serves as a footprint, from which according to a predetermined light distribution light in the main emission (H) is emitted.

According to an alternative embodiment, not shown, the second optical device 6 also be designed as a reflector or lens (Fresnel lens) or EdgeLight light guide.

The first optical device 3 is formed as a surface light guide, the opposite flat sides 3 ' as well as narrow sides 3 '' having. The light guide 3 has a length l1 equal to a length l2 of the rod-shaped optical fiber 6 is. The light guide 3 has a width b1 which is at least three times as large as a width b2 of the rod-shaped optical fiber 6 , The light guide 3 has a thickness d1 which is substantially smaller than a thickness d2 of the rod-shaped optical fiber 6 , The light guide 3 is formed substantially rectangular or cuboid.

In a corner area of the flat light guide 3 is the laser light source 2 arranged, by means of which a laser light beam 9 diagonally to the light guide 3 and coupled in parallel to its extension plane. The narrow sides 3 '' of the light guide 3 act as a deflection, where the laser light beam 9 is totally reflected. The laser light beam 9 thus strays within the fiber optic cable 3 around. Because the material of the surface light guide 3 consists of a scattering material is the course of the laser light beam 9 visible from the outside. Depending on the arrangement of the laser light source 2 and / or the shape of the surface light guide 3 and / or the irradiation direction of the laser light beam 9 in the surface light guide 3 Thus, a particular laser beam pattern is generated. A front flat side 3 ' of the surface light guide 3 serves as a footprint 10 , as the course of the laser light beam 9 within the surface light guide 3 is recognizable from the outside. For this purpose, the material of the surface light guide 3 such a degree of diffusion that the laser light beam extending substantially perpendicular to the main radiation direction H. 9 is recognizable as a group of lines or lines.

According to an alternative embodiment of the invention, not shown, the deflection means may also be formed by mirror elements and / or prism elements and / or reflectors, preferably in the surface light guide 3 are arranged integrated. In this way, a targeted laser light pattern in the surface light guide 3 be generated. Alternatively, the deflection can also on the edge region of the narrow side 3 '' the first optical device 3 be arranged.

The first light unit 1 can be used to generate a taillight or position light distribution. This is done essentially by the fact that in the surface light guide 3 integrated scattering elements allow a radiation of light in the main emission direction H. The actual laser light beam 9 becomes exclusively within the plane of extent of the surface light guide 3 redirected on the narrow sides 3 '' of the surface light guide 3 , A deflection of the laser light beam 9 in Hauptabstrahlrichtung is not provided. A deflection of the laser light beam 9 on the flat sides 3 ' is not scheduled. The light bundle generating the light function becomes due to the provision of scattering elements in the surface light guide 3 allows.

Optionally, the first light unit 1 also several laser light sources 2 Have (laser light diodes).

According to an alternative embodiment, not shown, also several surface light guides 3 be arranged one behind the other in the main emission direction H, preferably at a distance from one another, in order to ensure a three-dimensional laser effect or appearance.

According to an alternative embodiment not shown, the laser light source 2 Also be associated with a beam splitter, so that the emitted laser light beam is fanned out in partial laser beams. As a result, further laser light patterns can be generated.

In the present embodiment, the footprint 10 the first light unit 1 at least about three times as big as the footprint 8th' the second light unit 4 , Preferably, the footprint is 10 the first light unit 1 at least twice as large as the footprint of the second light unit 4 ,

According to a second embodiment of the invention according to 2 can the surface light guide 3 on opposite sides in each case a light guide 6 the second light unit 4 be assigned. Here, the light guides 6 in the main emission direction in front of the surface light guide 3 be arranged. In this way, the footprint 8th' the second light unit 4 be enlarged.

In the 2 to 5 are for ease of illustration only the optics 3 . 6 shown. Since they have the same structure as in the embodiment according to 1 they have the same reference numbers.

According to a further embodiment of the invention according to 3 can the rod-shaped light guides 6 also in the main emission direction H behind the surface light guide 3 be arranged. For example, adjacent light guides 6 be arranged at an equal distance from each other.

According to a further embodiment of the invention according to 4 can optical fiber 6 in the main emission direction H in front of the surface light guide 3 and a rod-shaped light guide 6 in Main emission direction behind the surface light guide 3 be arranged the first light unit.

According to a further embodiment of the invention according to 5 can the light guides 6 also in the plane of the surface light guide 3 be arranged integrated. As a result, the entire lighting device has a relatively small overall depth.

LIST OF REFERENCE NUMBERS

1

1st lighting unit

2

Laser light source

3, 3 '

1. Optical device / surface light guide

4

2nd lighting unit

5

LED light source

6

2. Optical device / optical fiber

7

front

8, 8 '

Lateral surface / illumination surface

9

Laser Beam

10

illumination area

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19746025 B4 [0002]

Claims (10)

Lighting device for vehicles with a first light unit comprising a laser light source and a laser light source associated with the first optical unit, characterized in that a second light unit comprising an LED light source and a second optical device associated therewith is provided, wherein a footprint ( 10 ) of the first optical device ( 3 ) is larger than a footprint ( 8th' ) of the second optical device ( 6 ). Lighting device according to claim 1, characterized in that the first optical device as a surface light guide ( 3 ) with opposite flat sides ( 3 ' ) and the same connecting narrow sides ( 3 '' ) is formed such that the laser light source ( 2 ) of a narrow side ( 3 '' ) of the surface light guide ( 3 ) and in the same a laser light beam ( 9 ), wherein the coupled laser light beam ( 9 ) via deflection means in the plane of extent of the surface light guide ( 3 ) is totally reflected across the main beam direction (H). Lighting device according to claim 1 or 2, characterized in that the surface light guide ( 3 ) consists of a material with such a degree of scattering that in the flat light guide ( 3 ) transverse to the main emission direction (H) extending laser light beam ( 9 ) is visible as a beam. Lighting device according to one of claims 1 to 3, characterized in that at least one laser light beam ( 9 ) in the surface light guide ( 3 ) can be coupled in an irradiation direction and / or the deflection means on or in the surface light guide ( 3 ) are arranged and / or the surface light guide ( 3 ) has a shape that over the footprint ( 10 ) of the surface light guide ( 3 ) a predetermined laser light beam pattern is recognizable. Lighting device according to one of claims 1 to 4, characterized in that the surface light guide ( 3 ) has such a degree of diffusion that a light beam for generating a given light function coupled out at the front flat side (footprint 10 ) in the main emission direction (H) can be emitted. Lighting device according to one of claims 1 to 5, characterized in that as deflection means for the laser light beam ( 9 ) a mirror element and / or a prism element and / or a reflector in the first optical device ( 3 ) or that deflecting means at the edge region of the narrow side ( 3 '' ) of the first optical device ( 3 ) are provided or that as a deflection the narrow side ( 3 '' ) of the surface light guide ( 3 ) is trained. Lighting device according to one of claims 1 to 6, characterized in that the laser light source ( 2 ) is assigned to a beam splitter for fanning the laser light beam ( 9 ). Lighting device according to one of claims 1 to 7, characterized in that the illumination surface ( 10 ) of the first optical device ( 3 ) is at least twice as large as the footprint ( 8th' ) of the second optical device ( 6 ). Lighting device according to one of claims 1 to 8, characterized in that the second lighting unit ( 4 ) in an edge region of the first lighting unit ( 1 ), wherein the second lighting unit ( 4 ) in the main emission direction (H) in front of the first lighting unit ( 1 ) is positioned. Lighting device according to one of claims 1 to 9, characterized in that the second lighting unit ( 4 ) in the main emission direction (H) in front of the first lighting unit ( 1 ) and / or behind the first light unit ( 1 ) is arranged on the one hand or that the second optical device ( 6 ) in the first optical device ( 3 ) is arranged on the other hand.

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