DE102016122861A1 - Lighting device for vehicles - Google Patents

Abstract

The invention relates to a lighting device for vehicles, in particular headlights, with a light source unit and with an optical unit for generating a predetermined light distribution, wherein the light source unit comprises a plurality of first laser diodes red light color delivery, second laser diodes green light color output and third laser diodes blue light color output that the light source unit a Having number of fiber couplers, wherein the fiber coupler is the input side connected to a plurality of laser diodes each via an optical fiber and the output side only via a single optical fiber with a light of the light source unit emitting light output field.

Description

The invention relates to a lighting device for vehicles, in particular headlights, with a light source unit and with an optical unit for generating a predetermined light distribution.

From the DE 10 2014 110 599 A1 a lighting device for vehicles is known, which has a light source unit and an optical unit for generating a predetermined light distribution. The light source unit comprises a plurality of laser diodes which emit light of different light color, namely red light color, green light color and blue light color. The optical unit has a plurality of lenses and a micromirror field in order to be able to generate the light distribution, for example a glare-free high beam. The known lighting device allows a light-intensive and homogeneous light distribution. A disadvantage of the lighting device is that it is relatively bulky.

Object of the present invention is therefore to develop a lighting device for vehicles with a plurality of laser diodes having light source unit such that the lighting device can be used to save space with little effort to produce different light distributions.

To achieve this object, the invention in conjunction with the preamble of claim 1, characterized in that the light source unit comprises a plurality of first laser light emitting diodes, second laser diodes green light color output and third laser light emitting blue light color output that the light source unit comprises a number of fiber couplers, wherein the fiber coupler is connected on the input side to a plurality of laser diodes via an optical fiber and on the output side only via a single optical fiber with a light of the light source unit emitting light emitting field.

According to the invention, a plurality of optical fibers and a fiber coupler are arranged between different light color emitting laser diodes and a light emitting field of a light source unit. Between the laser diodes and the fiber coupler extend optical fibers, which transmit light of different light color to an input of the fiber coupler due to the connection with different light color emitting laser diodes. Within the fiber coupler, a transition to a single optical fiber takes place, which on the output side guides or directs the light to the light emission field. Advantageously, light from different light color emitting laser diodes can thus be performed to a remote light emitting field. By the light fibers, which are each designed as optical waveguides, the laser diodes can be arranged in any position in the vehicle. They do not have to be installed directly in the headlight housing. Advantageously, the laser diodes can be arranged where optimal cooling of the same is ensured. Since the light emitting panel emitting the light of the light source unit can be disposed at an arbitrary angle and away from the laser diodes, the design possibilities in the headlight increase.

According to a development of the invention, the light emission field has a plurality of fiber ends of the light fibers arranged in a light emission surface or plane. Advantageously, a desired luminance or a desired luminous flux can be set to save space by selecting the number of optical fibers or the laser diodes.

According to a development of the invention takes place in the fiber coupler, a combination of color light fibers, each leading to a light of different light color, on the one hand and a white light fiber, the light of white light color, on the other hand. In the fiber coupler, additive color mixing takes place so that white light can be dissipated on the output side via the white-light fiber.

According to a development of the invention, a fiber end of the white light fiber has a cross section which corresponds at least to the cross section of the input side of the same fiber coupler arranged color light fibers.

According to a development of the invention, the fiber coupler has nine color light fibers on the input side and a single white light fiber on the output side. By energizing the individual laser diodes, a desired luminous flux and a desired light color can be set.

According to a development of the invention, the light-emitting field has a number of white-light fibers of a plurality of fiber couplers. Advantageously, the luminous flux can thus be further increased.

According to a development of the invention, a number of white-light fibers is followed by an optical unit which images the number of white-light fibers onto a light-shaping optical element. There is an optical image instead. By switching the individual white light fibers, it is possible to adapt the light distribution in front of the light-shaping optical element as a function of sensor data provided by a traffic space detection unit to the necessary glare control areas. Advantageously, less light is thus destroyed by the subtractive acting light-forming optical elements.

According to a development of the invention, a number of white light fibers are followed by an optical mixer (mixing rod, hexagonal rod) which is rectangular, hexagonal or polygonal. Advantageously, the aspect ratio of the light output field is adapted to the light-shaping optical element.

According to a development of the invention, an optical unit is arranged between the light emitting field and the light-shaping optical element, which optically adapts the round white-fiber end to the light-shaping surface of the light-shaping optical element. Preferably, the optical unit is a microlens array, a custom lens or a reflector.

According to a development of the invention, the light-emitting field has an area of 0.2 mm ² to 16 mm ^2, depending on the number of fiber couplers used. Advantageously, this light can be emitted from a relatively small area.

According to a development of the invention, the optical unit has a micromirror field or a liquid crystal panel or a microlens field or a reflector or at least one refractive lens and / or at least one diffractive lens. These preferably have individually controllable microelements, so that different light distributions, in particular apron and / or dimming and / or high beam distributions can be generated. Advantageously, for example, city, motorway, low beam and high beam can be generated by means of a single headlight.

According to a development of the invention, the lighting device can be controlled as a function of sensor data provided by a traffic space detection unit, so that a high beam distribution containing a glare range can be generated, wherein the other traffic object is located in the glare control area. It can be a dynamic tracking of Entblendungsbereiches to the traffic object, so that in this way an optimal light distribution or an adaptive light distribution can be provided.

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

• 1 eine schematische Darstellung einer Beleuchtungsvorrichtung nach einer ersten Ausführungsform,
• 2 eine Vorderansicht eines Lichtabgabefeldes einer Lichtquelleneinheit der Beleuchtungsvorrichtung und
• 3 eine schematische Darstellung einer zweiten Ausführungsform der Beleuchtungsvorrichtung.

Show it:

• 1 a schematic representation of a lighting device according to a first embodiment,
• 2 a front view of a light emitting panel of a light source unit of the lighting device and
• 3 a schematic representation of a second embodiment of the lighting device.

A lighting device according to the invention is preferably used as a headlight in a bow region of a vehicle in order to generate a predetermined light distribution, in particular an apron and / or low beam and / or high beam distribution.

The lighting device has a light source unit 1 containing a plurality of laser diodes 2 . 3 . 4 on, wherein a first laser diode 2 Light red light color, a second laser diode 3 Light green light color and a third laser diode 4 Light blue light color radiates. The first laser diode 2 emits light of wavelength 635 nm in a power range of 0.5 W to 2 W. The second laser diode 3 emits light of a wavelength of 520 nm in a power range of 1 W to 2 W. The third laser diode 4 emits light of a wavelength of 445 nm in a power range between 1 W and 4 W.

The light source unit 1 further comprises at least one fiber coupler 5 namely an Nx1 fiber coupler 5 on the input side over several, namely N, optical fibers 6 with several laser diodes 2 . 3 . 4 on the one hand and over a single optical fiber 7 with a light output field 8th the light source unit 1 connected is.

According to a first embodiment of the invention according to 1 the light fibers 6 are formed as color light fibers, which each transmit or guide light of a single light color. So is the fiber coupler 5 with the first laser diode 2 via a red light leading color light fiber 6 ' , with the second laser diode 3 a green light leading color light fiber 6 " and with the third laser diode 4 over a blue light leading color light fiber 6 '" connected.

The fiber coupler 5 are on the input side so N color light fibers ( 6 ' . 6 " . 6 "' ), consisting of x red colored light fibers ( 6 ' ), y green colored light fibers ( 6 " ) and z blue colored light fibers ( 6 "' ), where x, y, z ∈ ℕ and x + y + z = N are supplied.

The colored light fibers 6 ' . 6 " . 6 '" be in the fiber coupler 5 merged, preferably fiber ends of the color light fibers 6 ' . 6 " . 6 '" are arranged flush side by side. The fiber ends of the colored light fibers 6 ' . 6 " . 6 '" are preferably arranged so as to give a square or round or rectangular common face. It is assumed that a cross-section of the fiber ends of the colored light fibers 6 ' . 6 " . 6 '" runs in a circle. Following the color light fibers 6 ', 6 ", 6'", a fiber end closes 9 the output side optical fiber 7 on, preferably blunt at the end faces of the colored light fiber ends 6 ' . 6 " . 6 '" and overlapping the same. The light fiber 7 thus serves as a white light fiber 7 ' , the light of white light color to the light output panel 8th transferred.

In a present embodiment, there are eighteen fiber couplers 5 provided, in which the input side nine color light fibers 6 ' . 6 " . 6 "' , preferably six colored light fibers 6 ' red light color, two colored light fibers 6 " green light color and a colored light fiber 6 '" enter blue light color. On the output side is the white light fiber 7 ' (Output fiber) Light of white light color to the light output panel 8th transferred.

In 2 are the fiber ends 9 the output light fiber 7 as shown in the light-emitting panel 8th are merged. The light fibers 6 . 6 ' . 6 " . 6 ''' and the light fibers 7 . 7 ' each have a constant diameter and are circular in cross-section. The fiber ends 9 are merged so that they have a relatively large packing density, ie a compact light exit surface with a circular or square or rectangular contour arises. In the present embodiment, the eighteen fiber ends 9 a rectangular contour 10 with edge sides of 2.6 mm x 3.3 mm. The light output field 8th thus has a light-emitting area of less than 16 mm ² . The light output field 8th may have an area in the range of 0.1 mm ² to 16 mm ² , preferably 0.2 mm ² to 16 mm ² . With today's laser diodes 2 . 3 . 4 As a result, a luminous flux of at least 20,000 Im can be achieved. Per fiber coupler 5 a luminous flux of about 1,000 to 1,200 Im is generated.

In main emission H in front of the light-emitting panel 8th is one as a micromirror field 11 formed light-shaping optical unit with a plurality of micromirrors 12 arranged, by means of which a predetermined light distribution 13 can be generated. As an opening angle φ of the light output panel 8th due to the fiber ends 9 can be kept relatively small, can over 90% of the emitted luminous flux through the optical unit 11 be recorded. Advantageously, thereby the light losses in the light emission from the headlight can be kept low. The micromirrors 12 are each individually controllable, so that, for example, a city, motorway, low beam and / or high beam distribution can be generated.

If the micromirror field 11 can be controlled as a function of sensor data provided by a traffic space detection unit, a high beam light distribution containing a glare control area can be generated, wherein another traffic object is located in the glare control area. In particular, the Entblendungsbereich the location of the traffic object can be tracked so that an optimal illumination of the vehicle apron is always guaranteed without glare of the other traffic object.

Preferably, between the micromirror field 11 and the light output panel 8th an optical unit, preferably a lens or an optical system, arranged for the parallelization of the light, so that the micromirror field 11 parallelized light L meets.

According to an alternative embodiment of the invention, not shown, the optical unit has a liquid crystal panel having a plurality of pixels or a reflector having a plurality of microreflector surfaces or a microlens array having a plurality of microlenses, in particular a microlens array, and / or at least one refractive Lens and / or at least one diffractive lens. The pixels or microreflector surfaces or microlenses can - like the micromirrors 12 - Are controlled individually to produce corresponding different light distributions.

According to a second embodiment of the invention according to 3 is a light source unit 1' provided, in contrast to the embodiment according to 1 the fiber couplers 5 on the input side exclusively with a plurality of first laser diodes 2 or second laser diodes 3 or third laser diodes 4 are connected. The fiber coupler 5 are on the input side thus either red light leading optical fibers 6 or green light leading optical fiber 6 " or blue light leading optical fiber 6 '" fed. The feeding of fiber couplers 5 thus takes place only in a single spectral range. On the output side of the fiber coupler 5 is thus via the output light fiber 7 each light of the same light color to the light output field 8th guided, as the input side of the corresponding laser diodes 2 . 3 . 4 receive. Advantageously, by this variant of the invention, the number of laser diodes 2 . 3 . 4 be reduced to the same luminous flux at the light output panel 8th to create. In main emission direction H in front of the light-emitting panel 8th is an optical mixer, preferably a hexagonal rod 14 , arranged, the front side, the sum of the cross sections of the output fiber ends 7 captured and through additive color mixing white light at its optics unit 11 facing the end 16 radiates.

The same components or component functions of the embodiments are provided with the same reference numerals.

The light fibers 6 . 7 may be of any length such that the laser diodes 2 . 3 . 4 remote from the light output panel 8th can be arranged. In particular, the laser diodes 2 . 3 . 4 in a location, optionally outside the headlight housing, arranged on the optimal cooling of the same is guaranteed. The laser diodes 2 . 3 . 4 can be arranged to save space in a matrix at any location in the vehicle.

LIST OF REFERENCE NUMBERS

1,1 '

Light source unit

2

1. Laser diodes

3

2. Laser diodes

4

3. Laser diodes

5

fiber coupler

6,6 ', 6 ", 6'"

optical fiber

7,7 '

optical fiber

8th

Light output field

9

fiber end

10

contour

11

Micromirror array

12

micromirror

13

light distribution

14

optical mixer

15

The End

16

The End

H

main radiation

L

light

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 102014110599 A1 [0002]

Claims (10)

Lighting device for vehicles, in particular headlights, with a light source unit (1, 1 ') and with an optical unit (11) for generating a predetermined light distribution (13), characterized in that the light source unit (1, 1') comprises a plurality of first laser diodes ( 2) red light color delivery, second laser light emitting diodes (3) green light color output, and third light emitting diode blue light emitting diodes (4), the light source unit (1, 1 ') comprises a number of fiber couplers (Nx1 fiber couplers (5)), the fiber coupler (5) on the input side with a plurality of laser diodes (2, 3, 4) via in each case an optical fiber (6, 6 ', 6 ", 6"') and on the output side only via a single optical fiber (7, 7 ') with a light of the light source unit (1, 1 ') radiating light output field (8) is connected. Lighting device after Claim 1 characterized in that the light emitting panel (8) comprises a single or a plurality of fiber ends (9) disposed in a light emitting surface or in a light emitting plane of the optical fibers (7, 7 ') supplied by a plurality of fiber couplers (5). Lighting device after Claim 1 or 2 , characterized in that the fiber end (9) of the output side of the fiber coupler (5) discharged light fiber (7, 7 ') has a cross section at least that of an input fiber of the input side of the fiber coupler (5) supplied light fibers (6, 6', 6 ", 6 ''') corresponds. Lighting device according to one of Claims 1 to 3 , characterized in that the fiber coupler (5) on the input side, a number of red light-carrying optical fibers (6 ') and green light-carrying light fibers (6 ") and blue light-conducting optical fibers (6''') is fed, that in the fiber coupler ( 5), the color light fibers (6 ', 6 ", 6''') are brought together and following the same a single fiber end (9) of the output side formed as a white light fiber optical fiber (7) is arranged, so that on the output side via the white light fiber (7) White light is dissipated to the light output panel (8). Lighting device according to one of Claims 1 to 4 , characterized in that the fiber coupler (5) on the input side N color light fibers (6 ', 6 ", 6"'), consisting of x red color light fibers (6 '), y green color light fibers (6 ") and z blue color light fibers (6"' ), where x, y, z ∈ ℕ and x + y + z = N are supplied. Lighting device according to one of Claims 1 to 3 , characterized in that the fiber coupler (5) on the input side exclusively via the optical fibers (6, 6 ', 6 ", 6''') is connected to a plurality of laser diodes (2, 3, 4), the first laser diodes (2) only red light color or as a second laser diode (3) only green light color or as a third laser diode (4) only blue light color radiate, and that in the main emission (H) in front of the light output panel (8), an optical mixer (14), in particular a hexagonal rod is arranged , Lighting device according to one of Claims 1 to 6 , characterized in that the light emitting panel (8) has an area in the range of 0.1 mm ² to 16 mm ² . Lighting device according to one of Claims 1 to 7 , characterized in that the optical unit, one or more refractive lenses and / or diffractive lenses and / or microlens arrays, wherein the light is formed so that it on a drivable micromirror array (11) and / or on a liquid crystal panel and / or to a reflector containing a plurality of microreflector surfaces. Lighting device after Claim 8 , characterized in that the optical unit forms the light so that it is imaged on a controllable micromirror field, in particular a DMD chip or a liquid crystal panel or a micro reflector surface, and / or further light-shaping optics, which are individually controllable for generating different light distributions, in particular an apron and / or low beam and / or high beam distribution. Lighting device after Claim 8 or 9 , characterized in that the plurality of micromirrors (12) of the micromirror field (11) and / or the pixels of the liquid crystal panel and / or the microreflector surfaces of the reflector are individually controllable as a function of sensor data provided by a traffic space detection unit, comprising a high beam distribution a Entblendungsbereich can be generated, wherein in the Entblendungsbereich another traffic object is, and that the Entblendungsbereich the location of the traffic object is tracked in the traffic area.

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