EP3184883A1 - Light module for a lighting device of a motor vehicle - Google Patents

Abstract

A light module (105) for an illumination device of a motor vehicle for emitting a light emission distribution (32) is described. A light guide body (10) of a secondary optics device (8) comprises a light coupling section (12) which is arranged and configured so that at least a part of a secondary light beam (22) enters the light guide body (10) by means of the light coupling section (12), a light coupling-out section (FIG. 14) arranged and configured to emit the emission light distribution (32), and a reflector portion (16) arranged and formed so that light of the light entering through the light incident portion (12) into the light guide body (10) of the reflector portion (16) to the light extraction section (14) is deflectable.

Description

State of the art

The invention relates to a light module for a lighting device of a motor vehicle.

Automotive headlights having a laser light source are well known. Thus, motor vehicle headlights can be created, which reach at high illuminance, low geometric dimensions and high efficiency headlights of more than 500 m.

It is also known that a projection optical system has a multiplicity of transmitting and / or reflecting individual components. Exemplary is on the DE 10 2013 200 521 A1 directed.

Furthermore, it is known that, for example, in the case of a defect of a headlight comprising a laser light source, high-intensity laser light can escape to the outside. This creates a hazardous situation for other road users. In order to prevent accidents due to escaping laser light, active and passive safety devices are known.

For example, in the DE 10 2012 220 472 A1 proposed a vehicle lighting device comprising a Abstrahlhemmungsmittel which is designed and arranged such that the deformation is suppressible in the Abstrahllichtverteilung for such light bundles which extend in a primary space angle range about a Primärärastrahlrichtung.

The DE 10 2012 220 481 A1 In contrast, a light module for motor vehicle headlamps, which comprises at least one detection device, which is designed and arranged so that it is detectable, when a radiation intensity of light bundles, which extend in the beam path to a photoluminescent element in a primary space angle range about a primary beam axis exceeds a safety threshold.

Disclosure of the invention

The object of the invention is thus to reduce the dimensions of a light module with a laser light source, the radiation of potentially dangerous laser light is simply and compact prevented.

The object underlying the invention is achieved by a light module according to claim 1. advantageous Further developments are specified in the dependent claims and can be found further in the following description of exemplary embodiments.

It is proposed a light module for a lighting device of a motor vehicle for emitting a Abstrahllichtverteilung. A laser light source and a primary optics device are designed to generate a primary light beam comprising laser light. A photoluminescent element is arranged such that the primary light beam strikes the photoluminescent element, and that from the incident primary light beam a secondary light beam comprising white light which can contain laser light is generated. A one-piece secondary optics device consists of a light guide arranged in the beam path after the photoluminescent element. The light guide body comprises a light coupling section, which at least partially comprises a reflective layer to allow at least a first part of the secondary light beam to enter the light guide body by means of the light coupling section and to reflect a second part of the secondary light bundle and unconverted primary radiation back onto the photo luminescent element. The light guide body includes a light extraction section to radiate the emission light distribution. The light guide body further comprises a reflector section for deflecting light entering the light guide body through the light coupling section by means of the reflector section to the light coupling section. This Sekundöroptikeinrichtung allows a small and thus very compact laser headlights, since the entire projection optical arrangement manufactured in one piece and so can be arranged in the headlight. Thus accounts for example fasteners for the reflector section. Advantageously, a dazzle-free projection optical arrangement can thus also be created by means of the secondary optics device.

In an advantageous embodiment, the reflector section and the light coupling-in section are matched to one another such that a focal point of at least part of the reflector section is located outside the secondary optics device in the region of the photoluminescent element. Consequently, the photoluminescent element is likewise arranged outside and at a distance from the light guide body, as a result of which both the laser light source and the primary optics device can be arranged outside the light guide body for generating the primary light bundle. In addition, there are advantages for the cooling of the photoluminescent element.

In an advantageous embodiment, the Lichteinkoppelabschnitt is spherical and the associated center of curvature is located on or within the photoluminescent element. In this way, it is advantageously achieved that a coupling of light into the light guide body takes place without a substantial refraction.

Advantageously, in a development, a first focusing region of the primary optics assembly, in particular the focal point of the primary optics assembly, a second focusing region of the reflector section, in particular the focal point of the reflector section, and the center of curvature of the light coupling section coincide or overlap. Thus, the image of the white light generated by the photoluminescent element becomes improved in the emission light distribution

In an advantageous embodiment, the light coupling-in section is arranged and configured such that incident white light is substantially transmitted and light having a wavelength of the laser light is reflected back substantially onto the photo-luminescent element. This is achieved by a corresponding coating on the light coupling surface. This advantageously prevents the escape of dangerous laser radiation. In addition, the efficiency of the light module is improved, since laser light emitted by the photoluminescent element is deflected back onto it and used to generate further white light. This embodiment is particularly advantageous when using a laser light source that generates ultraviolet laser light. For example, ultraviolet light emitted from, for example, a laser light source and / or deflected by the photoluminescent element is prevented from entering the light guide body, which improves laser safety.

In an advantageous embodiment, the light guide body is arranged and configured such that light having a wavelength of the laser light is substantially absorbed between the light coupling section and the light coupling-out section and white light is substantially transmitted. This embodiment is particularly advantageous when using a laser light source that generates ultraviolet laser light. Thus, ultraviolet light is prevented from passing through the light guide body. Thus, a passive safety concept for laser light sources emitting ultraviolet laser light is provided, which equally allowed the creation of smaller headlights. Thus, active safety devices to increase the reliability of a motor vehicle headlamp can be omitted with a laser light source.

In an advantageous embodiment, the light outcoupling section is arranged and configured such that incident white light is substantially transmitted and light with the wavelength of the laser light is reflected back substantially into the light guide body. Thus, preferably no laser light emerges from the light module. This embodiment is particularly advantageous when using a laser light source that generates ultraviolet laser light. In particular, in conjunction with a light guide, which substantially absorbs light having a wavelength of the laser light, the passive safety can be additionally increased by the back-reflected light.

In an advantageous embodiment, a mirror surface facing the light coupling-in section directly adjoins a surface of the photoluminescent element. As a result, for example, a light-dark boundary can be imaged in the emission light distribution, which has a high light intensity up to its edge. For this purpose, the transition between the mirror surface and the surface is abrupt and at least partially rectilinear. This embodiment is particularly advantageous when using a laser light source that generates ultraviolet laser light. In particular, the efficiency is increased since the light-emitting section which is designed to be reflective with respect to the laser light directs the laser light reflected from the mirror surface back onto the photoluminescent element in order to generate white light In an advantageous embodiment, the light coupling-in section and / or the light coupling-out section comprises an antireflection coating. This embodiment is particularly suitable for laser light sources that generate blue laser light. Thus, light having a wavelength of the laser light, in particular scattered laser light generated by the photoluminescent element, passes through the light guide body. Thus, scattered laser light is included in the emission light distribution.

One embodiment relates to a light module arrangement comprising a first light module and a second light module, wherein the two light modules have a common light guide body. Advantageously, such a further reduction of the headlamp can be achieved while reducing costs.

One embodiment relates to a method for producing the light module, wherein the primary light beam is directed onto the photoluminescent element, wherein an actual position of a light spot of the laser light is determined on the surface of the photoluminescent element, and wherein a difference between the determined actual position of the light spot and a Target position of the light spot is determined.

A development of the method relates to an adjustment of the photoluminescent element and the secondary optics device as a function of the difference determined in relation to one another such that the actual position of the light spot substantially coincides with the desired position of the light spot.

Other features, uses and benefits of Invention will become apparent from the following description of embodiments of the invention, which are illustrated in the figures of the drawing. For functionally equivalent sizes and features, the same reference numerals are used in all figures, even in different embodiments.

Figur 1

eine Beleuchtungseinrichtung für Kraftfahrzeuge;

Figur 2a und 2b

eine schematische Schnittansicht eines Lichtmoduls;

Figur 3

ein schematisches Ablaufdiagramm;

Figur 4

in schematischer Form einen Teil eines Lichtleitkörpers; und

Figur 5

in schematischer Form eine Draufsicht auf ein Photolumineszenzelement.

Hereinafter, exemplary embodiments of the invention will be explained with reference to the drawings. In the drawing show:

FIG. 1

a lighting device for motor vehicles;

FIGS. 2a and 2b

a schematic sectional view of a light module;

FIG. 3

a schematic flow diagram;

FIG. 4

in schematic form a part of a light guide body; and

FIG. 5

in schematic form a plan view of a photoluminescent element.

In FIG. 1 a lighting device for motor vehicles is designated in its entirety by the reference numeral 101. The lighting device 101 is formed in the illustrated embodiment as a motor vehicle headlight. Of course, the lighting device 101 may also be designed as a light or the like which is arranged at the rear or laterally on the motor vehicle. The headlight 101 comprises a housing 102, which is preferably made of plastic is made. In a light exit direction 103, the headlight housing 102 has a light exit opening, which is closed by a transparent cover 104. The cover 104 is made of colorless plastic or glass. The disk 104 may be formed without optically effective profiles (for example, prisms) as a so-called clear disk. Alternatively, the disk 104 may be provided at least in regions with optically active profiles, which in particular cause a scattering of the light passing through in the horizontal direction.

Inside the headlight housing 102, two light modules 105, 106 are arranged in the illustrated embodiment. The light modules 105, 106 are arranged fixed or relative to the housing 102 movable. By a relative movement of the light modules 105, 106 to the housing 102 in the horizontal direction, for example, a dynamic cornering function can be realized. The light modules 105, 106 are for generating a desired light distribution, for example a low beam, a high beam, a city light, a highway, highway, fog, static or dynamic cornering or any other static or adaptive Light distribution formed. The light modules 105, 106 produce the desired light function either alone or in combination with each other by virtue of the light emission from each individual light module 105; 107 supplied partial light distributions are superimposed to the desired total light distribution. The light modules 105, 106 can be designed as reflection modules and / or as projection modules. Of course, more or fewer than the illustrated two light modules 105, 106 may be provided in the headlight housing 102.

FIG. 2a shows in a schematic sectional view of the light module 105. Of course, the comments on the light module 105 are also applicable to the light module 106. The light module 105 comprises in the beam path a laser light source 2, a primary optics device 4, a photoluminescent element 6 and a one-piece secondary optics device 8.

The one-piece secondary optics device 8 comprises a light guide body 10 which is at least partially delimited by a light coupling-in section 12 and a light coupling-out section 14. In the beam path between the Lichteinkoppelabschnitt 12 and the Lichtauskoppelabschnitt 14, a reflector portion 16 is arranged. Furthermore, the light guide 10 is made of a material transmitting white light, such as plastic or glass.

The laser light source 2 generates ultraviolet laser light which, after passing through the primary optics device 4, strikes the photoluminescence element 6 in a substantially focused manner as the first light beam 20. The primary optics device 4 can be designed as a transmission optics and / or reflection optics. The first light beam 20 is also referred to as a primary light bundle. The photoluminescent element 6 is mirrored on the back and generates a second light beam 22, which can also be designated as a secondary light bundle. The primary light bundle 20 preferably impinges on a surface 26 of the photoluminescent element 6 at a focal point 24 of the primary optics device 6. In particular, oblique incidence of light of the primary light bundle 20 on the photoluminescent element 6 can cause part of the laser light to be incident on the surface 26 of the photoluminescent element 6 Direction of the Lichteinkoppelabschnitts 12 are reflected.

In particular, a number of two to four laser light sources 2 with corresponding primary optics 4 can be arranged such that they direct their primary light bundles 20 onto a common photoluminescent element 6.

The secondary light beam 22 emitted by the photoluminescent element 6 into a half space strikes the light coupling section 12, through which at least part of the secondary light beam 22 enters the light guide body 10 as the third light beam 28. The Lichteinkoppelabschnitt 12 is formed spherically, wherein the center of curvature is located in the focal point 24 on the surface 26. The light coupling section 12 includes a reflective coating 25 which substantially reflects incident ultraviolet light. Thus, the ultraviolet light coming from the photoluminescent element 6 onto the light coupling section 12 is irradiated back to the photoluminescent element 6. By contrast, white light passes through the reflective coating 25 and enters the optical waveguide 10.
The light-guiding body 10 comprises the spherically formed light coupling-in section 12 and a parabolic reflector section 16. The reflector section 16 may be formed, for example, by a reflective coating or by an interface of the light-guiding body 10 on which total reflection occurs.

As a result of the spherical configuration of the light coupling-in section 12, light beams of the secondary light bundle 22 experience essentially no or only one low refraction. The primary optics 4, the Lichteinkoppelabschnitt 12 and the reflector portion 16 are coordinated and arranged to each other so that the focal point 24 of the primary optics 4 coincides with the focal point of the reflector portion 16 and the center of curvature of Lichteinkoppelabschnitt 12 or at least overlap the corresponding focus areas.

The reflector portion 16 transforms the third light beam 28 into a fourth light beam 30. The fourth light beam 30 includes collimated light directed to the light extraction section 14. The light extraction section 14 includes, for example, in a yz plane adjoining collecting and scattering sections to transform the fourth light beam 30 in a Abstrahllichtverteilung 32 or a high beam distribution. The light extraction section 14 is designed in particular for producing a low-beam light distribution. Of course, the Lichtauskoppelabschnitt 14 may be configured differently in terms of its shape. The light coupling-out section 14 measures, for example, in the z-direction between 20 and 40 mm and in the y-direction between 15 and 25 mm, whereby compact Lichtauskoppelabschnitt 14 can be arranged side by side, thus leading to a compact headlight.

In a first embodiment of the light module 105, the laser light source 2 radiates ultraviolet laser light. The photoluminescent element 6 is designed in such a way that at least part of the ultraviolet laser light striking the photoluminescent element 6 is converted into white light and as part of the secondary light beam 22 is emitted. The laser light source 2 emitting ultraviolet laser light which is directed to the photoluminescent element 6 has the advantage that the white light generated by the photoluminescent element 6 does not have to contain any portions of scattered laser light in order to add white light to the superimposition of all the contributions receive. Thus, it is possible to filter out the scattered ultraviolet laser light in the optical path. Furthermore, in particular of the surface 26 but also of deeper layers of the photoluminescent element 6, in particular of the back-side mirroring of the photoluminescent element 6, ultraviolet laser light is irradiated as part of the secondary light beam 22 into a space 34 between the photoluminescent element 6 and the light coupling section 12. The light coupling section 12 comprises a dichroic layer which transmits white light from the secondary light beam 22 into the light guide body 10 and reflects ultraviolet laser light substantially into the space 34 back onto the photo luminescent element 6. The light guide body 10 may be made of a material which substantially absorbs ultraviolet light in the beam path and substantially does not absorb white light in the beam path but transmits as far as the light coupling-out section 14. The light extraction section 14 may also be configured dichroic, so that the white light guided by the light guide body 10 is substantially transmitted and ultraviolet light is substantially reflected back into the light guide body 10. Of course, the first embodiment may also be provided without dichroic coatings in the region of the light coupling-in section 12 and / or of the light coupling-out section 14. Especially For example, the light-coupling section 12 is dichroic, so that more than 97% of the white light is transmitted and reflected by more than 90% of the ultraviolet light. In particular, the light extraction section 14 is configured to be dichroic, so that more than 97% of the white light is transmitted and reflected over 90% of the ultraviolet light.

FIG. 2b shows a second embodiment of the light module 105, in which the laser light source 2 emits substantially blue laser light. The photoluminescent element 6 converts blue laser light into scattered laser light and luminescent light, which is emitted in the form of white mixed light from the photoluminescent element 6. The light coupling-in section 12 comprises in sections a reflecting layer 27 for reflecting incident blue laser light back onto the photoluminescent element 6. Thus, an unused but potentially dangerous part of the blue laser light can be radiated back onto the photoluminescent element 6 and used for white light generation. Even with an impact of non-scattered blue laser light, the reflective layer 27 ensures that it is not coupled into the light guide 10.

Furthermore, the light coupling-in section 12 has a window 29 without reflecting layer 27 in order to introduce as large a part of the secondary light bundle 22 with luminescent light and scattered laser light into the light guide body 10. Consequently, the reflective layer 27 is interrupted in the region of the window 29. Unlike the in FIG. 2a Shown embodiment is scattered primary light, so scattered laser light for Generation of white light with needed. The optical waveguide 10 is designed to be transmissive in the beam path starting from the light coupling-in section 12 towards the light decoupling section 14 substantially for the mixed light emitted by the photoluminescent element 6. The light extraction section 14 comprises an antireflection layer.

The light module 105 can in the FIGS. 2a and 2 B have a light guide 10, which is additionally assigned to a further light module 106 as a common injection molded part.

FIG. 3 shows a schematic flow diagram 40 for producing the light module 105, 106. In a first step 42 laser light of the laser light source 2 is directed through the primary optics device 4 on the photoluminescent element 6. In a second step 44, an actual position of the light spot on the surface 26 of the photoluminescent element 6 is determined. This determination of the actual position of the light spot is effected by a recording by means of a camera. In a third step 46, a difference between the determined actual position of the light spot and a desired position of the light spot is determined. In a fourth step 48, depending on the difference determined, the photoluminescent element 6 and the secondary optics device 8 are adjusted to one another such that the actual position of the light spot substantially coincides with the desired position of the light spot. In particular, with respect to the wavelength of the laser light reflective trained Lichteinkoppelabschnitts 12 according to the aforementioned first embodiment, in this way, the reflected light from the Lichteinkoppelabschnitt 12 with the wavelength of the laser light can be focused on the focal point 24 of the primary optics device 4 on the photoluminescent element 6, so as to increase the efficiency of the light module 105 with respect to the white light generation.

As an alternative to the fourth step 48, for quality assurance, a photoluminescent element 6 already fixed to the secondary optics device 8 can be checked for its correct adjustment. In particular, if the difference between the actual position of the light spot and the desired position of the light spot is too great, the light module 105 can be discarded.

FIG. 4 shows in schematic form a part of the light guide 10 in a sectional view, wherein the reflector portion 16 is formed faceted. Thus, the reflector section 16 has facet elements 16a, 16b, 16b, which are assigned to the one photoluminescent element 6. Thus, the centrally arranged facet element 16b can serve for a central illumination of the roadway. The facet elements 16a and 16b can be provided for example for side illumination.
FIG. 5 shows in schematic form a plan view of the back-mirrored photoluminescent element 6. In the above-mentioned first embodiment, the surface 26, which is provided for the emission of white light from the photoluminescent element 6, immediately adjoins a mirror surface 50 facing the light-coupling section 12. This results in an edge 52 between the surface 26 and the mirror surface 50. The primary light beam 20 is in a focusing region 54, which in particular includes the focal point 24 and can be designated as a light spot, on the Photoluminescent element 6 focuses, so that the focusing region 54 lies partly on the mirror surface 50 and partly on the surface 26. By means of a focusing region 54 selected in this way, the edge 52 in the emission light distribution 32 is advantageously imaged in such a way that a high light intensity difference results. For example, the chiaroscuro limit can be better represented. In addition, laser light is reflected by the mirror surface 50 in accordance with the light beam 56 exemplified on the Lichteinkoppelabschnitt 12. The mirror surface 50 may, for example, be arranged as a coating on the surface 26 of the photoluminescent element 6. The light beam 56 with reflected laser light is exemplarily represented by the light coupling section 12 designed to be reflective for laser light by a light beam 58 back onto the photoluminescent element 6 in a feedback region 60 on the surface 26. The laser light reflected back into the feedback region 60 from the light coupling-in section 12 can thus be used for further white light generation and thus for increasing the efficiency.

In the above-mentioned second embodiment of the light module 105 with a laser light source which generates blue laser light, a light scattering and / or laser light absorbing surface facing the light coupling section 12 is arranged so as to be incident on the surface 26 of the photoluminescent element 6 as an alternative to the mirror surface 50 connected to also form an edge between the surface 50 and the absorption surface in order to achieve in the emission light distribution 32, for example, a high light intensity to the edge of the cut-off line.

Claims (13)

A light module (105, 106) for an illumination device (101) of a motor vehicle for emitting a light emission distribution (32), comprising: - A laser light source (2) and a primary optics device (4), which are designed to generate a primary light beam (20) comprising laser light; a photoluminescent element (6) which is arranged such that the primary light beam (20) strikes the photoluminescent element (6) in order to generate from the incident primary light beam (20) a secondary light beam (34) comprising white light; and a one-piece secondary optical device (8) with a light guide body (10) arranged in the beam path downstream of the photoluminescent element (6), wherein the light guide body comprises: - A Lichteinkoppelabschnitt (12), which at least partially comprises a reflective layer (27, 28) to a first part of the secondary light beam (22) by means of the Lichteinkoppelabschnitts (12) in the Lichtleitkörper (10) to enter and a second part of the secondary light beam (22) back to the photoluminescent element (6) to reflect; - A light extraction section (14) to emit the Abstrahllichtverteilung (32); and - A reflector portion (16) to redirect light by the Lichteinkoppelabschnitt (12) in the Lichtleitkörper (10) entering light by means of the reflector portion (16) to the Lichtauskoppelabschnitt (14). The light module (105; 106) according to claim 1, wherein the reflector section (16) and the light coupling section (12) are matched to each other such that a focus of at least a portion of the reflector section (16) is outside the secondary optics device (8) in the region of the photoluminescent element (6). The light module (105; 106) according to claim 1 or 2, wherein the light coupling portion (12) is spherical, and wherein the associated center of curvature is in or within the photoluminescent element (6). The light module (105, 106) according to claim 3, wherein a first focusing region of the primary optics assembly (4), in particular the focal point (24) of the primary tropic assembly (4), a second focusing region of the reflector section (16), in particular the focal point of the reflector section (16 ), and the center of curvature of the Lichteinkoppelabschnitts (12) overlap, especially coincide. The light module (105; 106) according to any one of the preceding claims, wherein the light coupling portion (12) is arranged and configured by its shape and by a special coating such that incident white light is substantially transmitted and light having a wavelength of the laser light substantially is reflected back to the photoluminescent element (6). The light module (105; 106) according to any one of the preceding claims, wherein the light guide body (10) is arranged and configured such that light having a wavelength of the laser light is substantially absorbed between the light coupling section (12) and the light coupling section (14) and white Light is substantially transmitted. The light module (105; 106) according to one of the preceding claims, wherein the light outcoupling section (14) is arranged and configured such that incident white light is substantially transmitted and light having the wavelength of the laser light is substantially reflected back into the light guide body (10) , The light module (105; 106) according to one of the preceding claims, wherein a mirror surface (50) facing the light coupling section (12) immediately adjoins a surface (26) of the photoluminescent element (6) with an at least partially rectilinear and abrupt transition. The light module (105; 106) according to any one of the preceding claims, wherein the laser light source (2) generates ultraviolet laser light. The light module (105; 106) according to one of claims 1 to 3, wherein the light coupling-in section (12) and / or the light coupling-out section (14) comprises an antireflection coating. The light module (105; 106) according to any one of claims 1 to 3 and 10, and wherein the laser light source (2) generates blue laser light. A method for producing the light module (105; 106) according to one of claims 1 to 11, characterized in that the primary light bundle (20) is directed onto the photoluminescent element (6) such that an actual position of a light spot on the surface (26) of the photoluminescent element (6) is determined, and that a difference between the determined actual position of the light spot and a desired position of the light spot is determined. An automotive headlamp (101) comprising one or more light modules (105; 106) according to any one of claims 1 to 11.

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