DE102016201040A1 - Lighting device and method for generating converted light - Google Patents

Abstract

The invention relates to an illumination device (16) for generating converted light with an excitation light source (18), a conversion medium (34) for converting the primary light (20) emitted by the excitation light source (18) into longer wavelength light and one in the beam direction of the primary light (20 ) arranged carrier device (22) for fixing the conversion medium (34). It is provided that the carrier device (22) has at least two subsections (24, 26), on each of which a conversion medium (34) is fixed, and the subsections (24, 26) are arranged relative to one another such that the primary light (20) successively encounters the conversion media (34) fixed on the subsections (24, 26). Furthermore, a method for generating converted light, in which a primary light (20) emitted by an excitation light source (10) is converted into longer-wavelength light, is provided, in which the primary light (20) is arranged on a conversion medium (22) arranged on a carrier device (22). 34) is blasted, wherein the primary light (20) is guided so that it successively on at least two subsections (24, 26) of the carrier device (32) impinges on each of which a conversion medium (34) is fixed.

Description

The invention relates to a lighting device for generating converted light with an excitation light source, a conversion medium for converting at least a portion of the excitation light into long-wavelength light and a carrier device arranged in the beam direction of the excitation light source for fixing the conversion medium and a method for generating converted light.

Such lighting devices are used, for example, in the automotive sector as vehicle lighting device, for example, as a headlight.

Such lighting devices serve to convert light emitted by a laser light source as primary light into secondary light having a longer wavelength. For example, the primary light has a wavelength of 450 nanometers (blue light) or 405 nanometers (violet light). The conversion produces what is known as white light, which is suitable for automotive lighting applications.

Such lighting devices are also referred to as remote lighting device, in which a laser primary light radiates to the conversion medium. This has a phosphor (phosphor), which converts the primary light. The conversion medium is fixed on a carrier device, which is formed for example by a non-transparent heat sink. The primary light is thereby reflected and then exits as secondary light again at the front of the conversion medium.

Such a remote phosphor lighting device is for example off DE 10 2012 223 857 A1 known. In this, a phosphor is removed from an associated semiconductor light source or spaced apart. Furthermore, a converter area which can be obliquely irradiated by the semiconductor light source is provided, wherein the main beam direction of the primary light, which has the highest radiation intensity, is not collinear with a surface normal of the irradiated surface of the converter area. The converter area is applied to an opaque base and thus in a reflective arrangement. A coupling-out optical system connected downstream of the converter area is arranged in a main beam direction of a secondary light generated by the converter area. The lighting device furthermore has at least one return-reflecting mirror which is arranged next to the main emission direction of the secondary light and is arranged and arranged to deflect back a primary light component which is reflected by the converter region onto the converter region. As a result, an otherwise lost or disturbing primary light component is to be reflected back to the converter area and converted there into secondary light again. This should lead to an increase in the light output.

The invention has for its object to provide a lighting device and a method of the generic type, by means of or in a simple manner, an optimal conversion of the radiated light from the excitation light source is possible.

According to the invention this object is achieved by a lighting device with the features mentioned in claim 1. The fact that the carrier device for fixing the conversion medium has at least two subsections, on each of which a conversion medium is fixed, and the subsections are arranged in such a way that the excitation light strikes the fixed on the subsections conversion media successively, is advantageously possible by the multiple reflection of the excitation light (primary light) to increase the overall conversion efficiency of the illumination device at the conversion media arranged one after the other in the beam direction. It is therefore provided at least a 2-fold reflection of the primary light. Thus, a simple conversion of the light emitted by the excitation light source is possible.

For the purposes of the invention, optimum conversion is understood to be achieved by the successive multiple reflection, that the short-wave component in the secondary light is reduced with each reflection. If, for example, an excitation light source with blue light, that is to say a wavelength of 450 nanometers, is used, the proportion of blue light is reduced with each reflection. Corresponding to the number of successive reflections, the proportion of blue light is reduced to the minimum amount of blue light necessary for white light generation. A complete conversion would not result in a high purity white light. The number of reflections required results from the conversion media used. The degree of purity of the long-wave light, so the white light, thereby increases.

In a preferred embodiment of the invention it is provided that the carrier device is arranged such that the primary light at an angle, preferably of 45 °, strikes a first portion and is reflected by this on at least one further portion. This advantageously makes it possible to align the conversion media fixed on the subareas in such a way that the primary light passes through the subregions in a cascade with the conversion media. In a first reflection of the primary light not yet converted shares are then converted in the following reflection on the at least one further subsection. The degree of conversion is thus increased with each reflection.

In a further preferred embodiment of the invention it is provided that the oppositely arranged sections are arranged such that there is a reflection channel in which there is a multiple reflection of the primary light. This advantageously makes it possible to provide the carrier device in a relatively small space and yet to allow a multiple reflection of the primary light.

Furthermore, it is provided in preferred embodiments of the invention that the opposite sections are arranged parallel to each other. As a result, a reflection channel is created in a particularly simple manner, which requires little space and in which the beam direction of the primary light is equal to the beam direction of the secondary light.

In a preferred embodiment of the invention, it is provided that a ratio of the length of the reflection channel to a width of the reflection channel is chosen so that there is at least a three-fold reflection of the primary light. In this way, it is advantageously achieved to increase the effectiveness of the illumination device and to reduce unconverted portions of the primary light with each further reflection.

In addition, in a further preferred embodiment of the invention, it is provided that a first section is planar and an opposite second section of the carrier device is curved. In this way, it is advantageously achieved that, in particular, the converted light, that is to say the secondary light, can be optimally imaged by the curved configuration of the further partial section. In particular, optical beam shaping of the secondary light is possible by selecting a curvature of the second subsection.

In addition, it is provided in a further preferred embodiment of the invention that the sections are arranged at an angle to each other, which is preferably 90 °.

By this arrangement is advantageously achieved to align the beam direction of the secondary light almost arbitrarily, in particular, if appropriate, to place it against the beam direction of the primary light. This makes it possible to create very compact lighting devices.

The object is further achieved by a vehicle light device the features mentioned in claim 9. By virtue of the fact that the vehicle lighting device comprises a lighting device according to the invention, it is advantageously possible to provide vehicle lighting devices in which excitation light sources with short-wave light, in particular laser light sources, can be used and an optimized white light is made available that is also particularly suitable for headlight systems.

A motor vehicle can thus be advantageously equipped with a vehicle lighting device, in particular a headlight system, which use a laser light source, wherein efficient utilization of the radiated laser power is possible.

The object is further achieved by a method having the features mentioned in claim 10. Characterized in that a primary light emitted by an excitation light source is guided so that it successively on at least two subsections of a carrier device, on each of which a conversion medium is fixed, is advantageously possible to achieve a multiple reflection of the primary light, with each further reflection of the proportion of the short-wavelength light is reduced in the reflected secondary light. Thus, it is particularly advantageously possible, upon reflection of a blue light having a wavelength of 450 nanometers, to increase the white component of the secondary light with each reflection to a mixed residual component.

Further preferred embodiment of the invention will be apparent from the other features mentioned in the dependent claims.

The invention will be explained below in embodiments with reference to the accompanying drawings. Show it:

1 a schematic plan view of a motor vehicle,

2 a carrier device according to the invention for a lighting device in a first embodiment,

3 a carrier device according to the invention for a lighting device in a second embodiment, and

4 a carrier device according to the invention for a lighting device in a third embodiment.

1 schematically shows a total with 10 designated motor vehicle in a plan view. The car 10 is known to have various vehicle lighting devices, such as headlights, tail lights, flashing lights and the like. A vehicle light device 12 is for example of headlights 14 educated. The headlights 14 include, inter alia, one based on the following 2 to 4 exemplified lighting device 16 ,

The lighting equipment 16 are shown purely schematically, wherein like parts are each provided with the same reference numerals.

The lighting device 16 includes an excitation light source 18 by means of a primary light 20 is emitted. The excitation light source 18 is, for example, a laser light source, by means of which, for example, blue light with a wavelength of 450 nanometers or violet light with a wavelength of 405 nanometers is emitted.

The lighting device 16 further comprises a carrier device 22 that is a first subsection 24 and a second subsection 26 having.

The carrier device 22 owns each subsection 24 and 26 an opaque underlay 28 , The underlay 28 is formed for example by a heat sink. The sections 24 and 26 are arranged so that between them a reflection channel 30 formed. At the side facing the reflection channel side of the sections 24 and 26 is each a mirror image 32 and on each of these a conversion medium 34 arranged. The conversion medium 34 is formed, for example, by a phosphor layer.

The documents 28 For example, it consists of a metal, for example aluminum or glass. Both the mirroring 32 as well as the conversion medium 34 can on the pad 28 be evaporated.

In the event that the pad 28 itself already has a reflective surface, can on the mirroring 32 be waived.

The lighting device 16 further comprises a coupling-out optical system 36 ,

At the in 2 embodiment shown are the sections 24 and 26 arranged parallel to each other. At the in 3 shown embodiment, the subsection has 24 a flat document 28 and the subsection 26 a concave in the direction of the reflection channel 30 curved underlay 28 , At the in 4 pointed example, the subsections 24 and 26 at an angle α to each other, here arranged by 90 °.

That of the excitation light source 18 emitted primary light 20 meets at an angle, from here 45 ° to the conversion medium 34 of the first section 24 , From this it is reflected, here at an angle of 45 °, so that it then on the conversion medium 34 of the second subsection 26 meets. From this it is again at an angle, here 45 °, reflected, so that at the output side of the reflection channel 30 a secondary light 38 exit. The conversion medium, here the phosphor coating, becomes the primary light 20 in a secondary light 38 with larger wavelength, such as white light converted.

By the successive impingement of the primary light 20 on at least two conversion media 34 becomes the overall conversion efficiency of the lighting device 16 elevated. There is an optimal conversion of the excitation light source 18 emitted primary light 20 , up to the desired degree of conversion.

At the in 2 Shown embodiment is a length L of the reflection channel 30 chosen to its width B so that at least three times, here four times the reflection of the primary light 20 he follows. This gives us a particularly high overall conversion efficiency. At the in 2 shown embodiment, the beam direction of the primary light 20 in the same direction as the beam direction of the secondary light 38 ,

At the in 3 example given by the curved formation of the pad 28 of the second subsection 26 a very accurate beam shaping of the secondary light 38 on the decoupling optics 36 possible. An imaging accuracy of the secondary light 38 is thus increased.

At the in 4 shown embodiment is characterized by the mutually angular arrangement of the sections 24 and 26 achieved that the beam direction of the primary light 20 and the beam direction of the secondary light 38 are opposite. This allows a particularly compact arrangement for the lighting arrangement 16 achieve.

The decoupling optics 36 ultimately forms the abstract appearance of the headlights 14 of the motor vehicle 10 ,

LIST OF REFERENCE NUMBERS

10

motor vehicle

12

Vehicle lighting device

14

headlights

16

lighting device

18

Excitation light source

20

primary light

22

support device

24

first section

26

second subsection

28

document

30

reflection channel

32

silvering

34

conversion medium

36

output optical system

38

secondary light

L

length

B

width

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 102012223857 A1 [0005]

Claims (10)

Lighting device ( 16 ) for generating converted light with - an excitation light source ( 18 ), - a conversion medium ( 34 ) for converting at least a portion of that of the excitation light source ( 18 ) emitted primary light ( 20 ) in longer-wavelength light and - one in the beam direction of the primary light ( 20 ) arranged carrier device ( 22 ) for fixing the conversion medium ( 34 ), characterized in that the carrier device ( 22 ) at least two subsections ( 24 . 26 ), on each of which a conversion medium ( 34 ), and the subsections ( 24 . 26 ) are arranged in such a way that the primary light ( 20 ) successively to those on the subsections ( 24 . 26 ) fixed conversion media ( 34 ) meets. Lighting device ( 16 ) according to claim 1, characterized in that the carrier device ( 22 ) is arranged such that the primary light ( 20 ) at an angle to a first section ( 24 ) and from this to the at least one further subsection ( 26 ) is reflected. Lighting device ( 16 ) according to one of the preceding claims, characterized in that the subsections ( 24 . 26 ) are arranged opposite one another such that a reflection channel ( 30 ) by giving a multiple reflection of the primary light ( 20 ) he follows. Lighting device ( 16 ) according to one of the preceding claims, characterized in that the opposing sections ( 24 . 26 ) are arranged parallel to each other. Lighting device ( 16 ) according to claim 4, characterized in that a ratio of the length (L) of the reflection channel ( 30 ) to its width (B) is selected such that at least three times the reflection of the primary light ( 20 ) he follows. Lighting device ( 16 ) according to one of the preceding claims, characterized in that a first subsection ( 24 ) a flat base ( 28 ) and an opposite subsection ( 26 ) a curved base ( 28 ) having. Lighting device ( 16 ) according to claim 6, characterized in that the curved section ( 26 ) concave with respect to the beam direction of the primary light ( 20 ) is trained. Lighting device ( 16 ) according to claim 3, characterized in that the subsections ( 24 . 26 ) are arranged at an angle (α) to each other. Vehicle light device ( 12 ), characterized by a lighting device ( 16 ) according to at least one of claims 1 to 8. Method for generating converted light, in which one of an excitation light source ( 10 ) emitted primary light ( 20 ) is converted into longer-wavelength light by the primary light ( 20 ) on a on a carrier device ( 22 ) arranged conversion medium ( 34 ) is blasted, characterized in that the primary light ( 20 ) is guided in such a way that it is successively divided into at least two subsections ( 24 . 26 ) the carrier device ( 32 ), to each of which a conversion medium ( 34 ) is fixed.

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