Lighting device for a motor vehicle

专利摘要:
The invention relates to a lighting device (100), in particular for a motor vehicle, comprising at least one laser light source (10), a wavelength conversion element (20) which is adapted to excite light from the at least one laser light source (10). and a reflector (30) having at least one reflector body (30 '), which at least one reflector body (30') comprises a reflection surface (31), which reflection surface (31) emitted by the wavelength conversion element (20) in the visible wavelength range Reflected light, wherein the reflector (30) on its the reflection surface (31) carrying the reflector surface (30a) is provided with the reflection surface (31), wherein the reflector surface (30a) at least one region (30a ', 30a' '), which is free of the reflection surface (31), and wherein the reflector surface (30a) at least in the region (30a ', 30a' '), which is free of the reflection surface (31), so far e is formed that in the area (30a ', 30a' ') incident excitation light is at least partially absorbed.
公开号:AT516554A1
申请号:T50854/2014
申请日:2014-11-26
公开日:2016-06-15
发明作者:Martin Schragl；Christian Bemmer
申请人:Zizala Lichtsysteme Gmbh；
IPC主号:

专利说明:

Lighting device for a motor vehicle
The invention relates to a lighting device, in particular for a motor vehicle, comprising: at least one laser light source; a wavelength conversion element configured to receive excitation light from the at least one laser light source; and a reflector having at least one reflector body, which at least one reflector body comprises a reflection surface, which reflection surface reflects the light emitted by the wavelength conversion element in the visible wavelength range, the reflector being provided with the reflection surface on its reflector surface carrying the reflection surface.
Furthermore, the invention relates to a motor vehicle headlight with at least one such lighting device and a motor vehicle with at least one such lighting device or with at least one such motor vehicle headlight.
Laser light sources (e.g., semiconductor lasers, laser diodes) have a number of special advantageous properties, such as e.g. high radiation intensities and a small light-emitting surface. In addition, the emitted light beams are largely collimated.
As a result, the use of laser light sources for illumination purposes has a number of advantages, e.g. Optical systems in which a laser light source is used as the light source can be realized with smaller focal lengths and more focused beam paths. This is not possible with less strongly collimated light bundles (for example of incandescent or light-emitting diodes (LEDs)). Thus, when using laser light sources, it is possible to realize optical systems for laser light with a small installation space.
Lasers typically emit monochromatic light or light in a narrow wavelength range. In a car headlight, however, is radiated for the
Light white mixed light desirable or required by law, so that laser light sources in a motor vehicle headlight can not be used easily.
In addition, the use of laser light sources has the problem that they can be dangerous, especially to the human eye. This is because lasers typically emit coherent and highly collimated light, which is potentially dangerous at the typical high radiation intensities of laser light sources. This is especially true at radiation powers of a few watts, as is desirable in the field of automotive lighting.
Therefore, in order to be able to use laser light sources in the motor vehicle sector, in particular for motor vehicle headlamps, safety regulations for the operation of laser devices must be ensured. In particular, it must be ensured that light (laser light) escapes from a motor vehicle headlight only at an intensity below prescribed limits. In addition, dazzling or endangering road users must be avoided.
In addition, compliance with the safety requirements must be ensured even if the lighting device is deformed or misaligned, such as by mechanical action, in an accident or by a mounting error. Even in these cases, compliance with the safety regulations for the operation of laser systems must be ensured for the lighting device or the motor vehicle headlights.
For conversion of monochromatic light into white or polychromatic light, so-called conversion elements (also referred to in this text as wavelength conversion element) are frequently used in connection with white light-emitting diodes (LEDs) or luminescence conversion LEDs. Such a conversion element is e.g. in the form of a photoluminescent converter or photoluminescent element or comprises at least one photoluminescence converter or at least one photoluminescent element. These usually have a photoluminescent dye.
The light of a typically colored (eg, blue) light (also referred to as "excitation light") excites the photoluminescent dye for photoluminescence, whereupon the photoluminescent dye itself emits light of other wavelengths (eg, yellow.) In this way, a portion of the irradiated As a rule, a further portion of the incident light (excitation light) is scattered and / or reflected by the photoluminescent element, and the scattered and / or reflected light and the light emitted by photoluminescence superimpose on each other The mechanism of photoluminescence can be differentiated depending on the lifetime of the excited state into fluorescence (short life) and phosphorescence (long life).
In the conversion elements, a distinction is made between reflective and transmissive conversion elements. In the case of reflective conversion elements, the light converted by the conversion element is emitted on the same side on which the excitation light strikes the conversion element. In transmissive conversion elements, the converted light is emitted from the side facing away from the side where the excitation light impinges.
When using conversion elements in motor vehicle headlights in connection with a laser light source, the conversion element has a high safety significance. If the position of the conversion element is changed or the conversion element is destroyed (for example by mechanical action, accident, manufacturing defect or design error), highly concentrated laser beams can emerge from the motor vehicle headlight.
It is an object of the present invention to provide an illumination device for motor vehicles mentioned at the beginning, wherein the illumination device has at least one laser light source in such a way that the danger of escaping excitation light from the laser light source is largely avoided and the illumination device meets the safety requirements prescribed by law, for example equivalent.
This object is achieved with an illumination device mentioned in the introduction in that, according to the invention, the reflector surface has at least one region which is free of the reflection surface, and wherein the reflector surface is embodied such that in the region at least in the region which is free of the reflection surface Area incident excitation light is at least partially absorbed.
By providing at least one region on the reflector surface, which at least partially absorbs excitation light from the laser light source which impinges on this region, excitation light via the reflector into the exterior space of the illumination device only weakens or no longer occurs in the event of a fault out.
Preferably, an absorbing region is to be arranged on the reflector or on the reflection surface of the reflector such that it lies in that region which would be hit by the excitation light from the laser light source, for example if the conversion element has been misaligned, porous or even omitted , or it is provided that an absorbing surface is located in a region in which excitation light is emitted by the conversion element.
In principle, the at least one region which at least partially absorbs excitation light can be formed from any desired material, it merely has to be ensured that sufficient excitation light is absorbed by it in the event of a fault. The absorbing area is preferably adapted for each system, i. E. on the intensity of the light source, which emits excitation light, focusing the spot, etc. tuned. For a low power light source, e.g. already sufficient to exploit the absorption of a non-vaporized and not blackened plastic (see the explanation below for this exemplary embodiment), with higher power light sources, it may be necessary to blacken the exposed area to obtain sufficient absorbing properties ,
The absorbing area is e.g. polycarbonate ("PC", e.g., macroion, Apec, etc.), PBT (polybutylene terephthalate), or ABS (acrylonitrile-butadiene-styrene) In addition, the absorbing portion may be formed black colored to increase the absorption.
It can be provided that the reflector surface is coated with a reflective material which forms the reflection surface. In such a reflector can then be provided that in the at least one area which is free of the reflection surface, the reflector surface is not coated with the reflective material or the reflective material is removed after coating in the at least one area, so on apt Excitation light is at least partially absorbed at the reflector surface.
For example, in this case, the reflector body is formed of a material (such as PC, ABS, PBT) described above, so that in the region in which the reflection surface is "omitted", absorption of at least the excitation light at the reflector surface of the reflector body occurs can.
The reflective surface (reflection surface) will be in the affected area (which is to absorb excitation light) during surface fabrication, e.g. by means of a surface coating process (e.g., vapor deposition, chrome plating, sputtering, etc. of the reflector surface) by means of e.g. Free fibers or covering or masking are made free of reflective material, so that an excitation light-absorbing surface is formed at the or the correspondingly processed areas.
It can also be provided that the reflector body has at least one passage opening, and wherein the at least one passage opening is closed by a closure element, wherein the surface of the closure element, which lies on the side of the reflection surface, surrounds the Excitation light forms at least partially absorbing area. "Substantially" irrespective of the type of production means that the embodiment described above can be used with basically arbitrarily produced reflectors, but that there may be production variants which may be preferred.
It is also possible for two or more excitation-light-absorbing regions to be provided in the case of a reflector, and these can also be realized in different ways as described above.
In the case of the last-mentioned embodiment, it is preferably provided that the surface of the closure element closes off the through-opening over the entire surface, so that no optical interference regions occur in the region between the closure element and the reflector.
It is particularly advantageous if the closure element is designed in such a way and / or inserted into the passage opening in such a way that the surface merges substantially continuously into the reflection surface.
In this way it can be ensured that in the transition region between the surface of the passage opening and the reflection surface no adverse optical effects (for example scattering of the excitation light and / or the mixed light) occur.
In the embodiment in which the reflector surface is provided with the reflective surface leaving one or more regions free of the reflective surface, the reflective surface is so thin in typical manufacturing processes that even when a region is left free In terms of lighting technology, there is a de facto steady transition.
Regardless of the design of the excitation light absorbing region, it is advantageous if the at least one excitation light absorbing region is designed such that the excitation light is largely or completely absorbed.
In large part, this means that at least 70% of the incident excitation light is absorbed. Preferably, the degree of absorption is at least 90%, more preferably 99%, especially 99.99%.
In one embodiment of an absorbent region, it is provided that an absorbent region is made temperature-resistant. In the absorption of the incident light, in particular excitation light, this area heats up, the temperature resistance ensures that this does not deform or melt.
In another embodiment of an absorbent region, it is provided that this at least one absorbent region above a limit temperature is not formed temperature-resistant.
For example, the limit temperature is 120 ° C.
The limit temperature is, for example, a melting temperature at which the material of the absorbing region begins to melt. The limit temperature may also be a decomposition temperature at which the material begins to decompose.
The temperature resistance of the material of the absorbent region depends, for example, on the color of the material, for example, by admixing additives (such as carbon black particles to obtain a black material) into, for example, a granulate from which the absorbent region is produced, e.g. produced by injection molding, are influenced.
If the absorbing area heats up above the respective limit temperature, the absorbing area is destroyed by melting or burning, and the excitation light can then enter the rear of the lighting device, where it loses and thus poses no danger.
As already mentioned, it is particularly advantageous if an excitation light-absorbing region is arranged in or on the reflector surface in such a way that excitation light and / or excitation light impinging directly on the reflector surface from the laser light source originates from is emitted to the conversion element, impinges on the absorbing region.
Thus, in particular in the case of a problem with the conversion element, for example if it is porous, destroyed or misaligned, it can be ensured that the excitation light reaches the absorbing region where it is, at least partially, preferably largely absorbed, in particular completely.
It can be advantageous if an absorbing region is arranged in such a way and with respect to its surface extension that the entire excitation light impinging directly on the reflector surface from the laser light source and / or the entire excitation light which emits from the conversion element will hit the absorbent area.
In this case, excitation light, which is emitted by the conversion element to the reflector and could be deflected from the reflection surface to the outside, at least partially, preferably for the most part, in particular completely absorbed.
There may also be provided two or more absorbent regions, either all of the same type, or at least one absorbent region of the type first described above and at least one absorbent region of the type of absorbent region described above as the second variant. The term "type" refers to the arrangement of the absorbing region with respect to the laser light source or the conversion element.
It is particularly preferred if an absorbing region is arranged in such a way and with respect to its surface extension that the entire excitation light impinging directly on the reflector surface from the laser light source and / or the entire excitation light emitted by the conversion element , exactly hits the absorbent area.
In this way, the entire excitation light reaches the absorbing area, with minimal size of the absorbing area.
In principle, thermosets or elastomers are preferably used as materials for the excitation light-absorbing region, wherein elastomers prove to be advantageous in particular in connection with a closure element, that is to say that the closure element is formed from the elastomer. Thermoplastics have, in contrast to thermoplastics, which are in principle also suitable, the advantage that these decompose (burn) from a certain limit temperature (decomposition temperature), it thus does not come to an uncontrolled melting and tearing as a liquid plastic. Elastomers, if they are not thermoplastic elastomers, have comparable good properties as thermosets.
The absorbent properties of the absorbent region are obtained, for example, by the dark, in particular black, color of the respective material in the absorbent region.
In the following the invention is discussed in more detail with reference to the drawing. In this shows
1 is a schematic representation of a first embodiment of a lighting device according to the invention,
2 is a schematic representation of a second embodiment of a lighting device according to the invention,
3 shows an enlarged detail from FIG. 1 in the region of the absorbing region,
FIG. 4 shows an enlarged detail of FIG. 2 in the region of the absorbent region formed by a closure element, and FIG
Fig. 4a shows the detail of Figure 4 prior to insertion of the closure element in the reflector.
FIG. 1 shows a lighting device 100 which comprises a laser light source 10, a conversion element 10 and a reflector 30. The laser light source 10 emits excitation light 200 ("primary light"), which impinges on the conversion element 20, is converted by this as described above, for example, into white mixed light 202, emitted from the conversion element 20 to the reflector 30 and from there to the outside to Forming a light distribution is emitted.
The light distribution that can be generated with the lighting device is, for example, a low beam distribution, a high beam distribution, a part of a low beam or high beam distribution, a cornering, cornering, highway, fog, bad weather or flashing light distribution, etc ., or one or more parts thereof.
FIG. 2 likewise shows a lighting device 100 for which the statements made above apply identically.
The difference between the illumination devices 100 in FIGS. 1 and 2 is in the nature of the conversion element 20 and, as a result, the other arrangement.
The illumination device 100 according to FIG. 1 has a transmissive conversion element 20 which emits mixed light 202 at least on its side / surface facing away from the laser light source 10. In effect, light can be emitted in all directions from the conversion element, and e.g. For example, optical devices in front of the conversion element, which act as a filter, can be used so as to be able to use the reflected-backconverted light, but the further optical system is located on the side / surface facing away from the laser light source.
Excitation light 200, which strikes the conversion element 20, strikes the reflector 30 in the beam cone 201 primarily in the presence of an error case described above. Accordingly, an excitation light absorbing region 30a 'on the reflector 30 in FIG a region of the reflector, which is hit by the excitation light cone 201 (exactly speaking, the sectional area between the reflector surface and the cone 201) is provided so that excitation light 201, which impinges on the reflector, is absorbed.
The illumination device 100 according to FIG. 2 has a reflective conversion element 20 which emits mixed light 202 on its side / surface facing the laser light source 10. Excitation light 200, which strikes the conversion element 20, is reflected in the beam cone 201 onto the reflector 30, primarily in the presence of an error case described above. Accordingly, an excitation light absorbing region 30a "is provided on the reflector 30 in a region of the reflector which is hit by the excitation light cone 201 (exactly, the sectional surface between the reflector surface and the cone 201), so that excitation light 201, which hits the reflector, is absorbed.
FIG. 2 shows only schematically the conversion element. Often this is arranged on a carrier or comprises a carrier, which is preferably designed to be reflective, so that the mixed light is emitted in a higher yield. In case of error, e.g. the falling of the conversion element of the carrier, however, the security risk is significantly increased by reflections of the laser beam to the reflective support. With the embodiment according to the invention as described above, this risk can be significantly reduced.
1 and 2 show different embodiments of an absorbing region 30a1, 30a "on the respective reflector 30. It should be noted that the embodiment of the absorbing region of the lighting device 100 of FIG can be implemented instead of the absorbent region 30a "shown there, and likewise the absorbent region 30a" described in detail in accordance with the illumination device according to FIG. 2 can also be embodied in the reflector FIG. 1 instead of the absorbent region 30a 'shown there Furthermore, it is also conceivable for a lighting device to have two or more absorbing regions for excitation light, as shown in the two figures, These absorbing regions can be of identical design, but they can also be implemented differently Absorbent areas, as shown below, may be implemented together in a lighting device.
FIG. 3 shows a detailed detail from FIG. 1. Shown is a section of the reflector 30, this reflector 30 consisting of a reflector body 30 ', and this reflector body 30' comprising a reflection surface 31 which generates the light generated by the wavelength conversion element 20, reflected light or mixed light in the visible wavelength range. As already explained with reference to FIG. 1, this reflected light subsequently generates a light distribution in the outer space in front of the illumination device.
The reflection surface 31 is applied to one side of the reflector 30, namely on the so-called reflector surface 30a of the reflector body 30 '. For example, the reflector surface 30a may be coated with the reflection surface 31, as will be explained in more detail below. The reflection surface 31 is formed from a light-reflecting material in order to be able to reflect the light lying in the visible wavelength range as already described above.
According to the invention, the reflector surface 30a now has a region which is free of the reflection surface 31. This free region represents an excitation light-absorbing region 30a 'which completely absorbs excitation light incident on it at least partially, preferably for the most part or particularly advantageously. The excitation light absorbing region 30a ', which is free from the reflection surface 31, can be produced in such a way that when applied, e.g. Coating the reflector surface 30a in the desired area is not provided with the reflective material, e.g. For example, the area may be masked or otherwise covered before the application of the reflective material so that no material forming the reflective surface 31 will be deposited in this area. But it is also possible that the entire reflector surface 30a initially provided with the reflective material, for example, is coated and then in the desired area, which is to act to absorb at least the excitation light, the reflection surface 31 is removed again.
The absorbent region 30a 'is thus formed from the "base material" forming the reflector body 30', which base material consists of a light-absorbing material, in particular the excitation-light-absorbing material This base material is eg made of PEI (polyetherimide) or PC (polycarbonate) formed or contains one of these materials, which have a high temperature resistance.
FIG. 4 and FIG. 4 a show a reflector 30 from FIG. 2 in a detailed view. In the embodiment shown, in turn, the reflector 30 has a reflector body 30 ', wherein the reflector body 30' is provided with a reflection surface 31. In the embodiment shown, the reflector 30 thus again consists, as shown in FIG. 1, of the reflector body 30 ', which has a reflector surface 30a on which the reflection surface 31 is applied, for example coated. However, it can also be provided in this embodiment that, for example, the entire reflector 30 is already formed from a reflective material, that is to say that the reflector body 30 'and the reflection surface 31 are integrally formed. In this case, the terminological subdivision into reflector surface and reflection surface is omitted.
In the embodiment shown according to Figure 2 and Figures 4, 4a is provided, regardless of the specific nature of the design of the reflector 30 (see paragraph above), that the reflector 30 and reflector body 30 'has a through hole 32, said passage opening 32 with a closure element 33 can be closed. The surface 33 'of the closure element 33, which lies in the inserted state of the closure element 33 on the side of the reflection surface 31, forms the excitation light at least partially, preferably largely or completely absorbing region 30a ". Preferably, as shown in FIG is, the closure element 33 is formed such that in the inserted state, the surface 33 'of the closure element 33 closes the through hole 32. In particular, it is advantageous if the surface 33' of the closure element 33 connects substantially continuously to the reflection surface 31.
The closure element 33 is preferably formed from an absorbent material (as already mentioned, for example, made of polycarbonate, PBT or ABS). With the closure element 33, the passage opening 32 is preferably covered by the rear or outer side of the reflector body 30 'or preferably closed by inserting the correspondingly adapted to the passage opening 32 closure element 33 in the passage opening 32 as described above.
The shutter member 33 may be formed of a material that is absorbent and resistant to the temperature input by the irradiated laser light (excitation light), so that the laser light is absorbed and does not leave the lighting device. However, it is also possible to use absorbent material which is not resistant to the temperature input by the laser light. In this case, for the time being, the laser light is absorbed at the absorbing region 30a "until the sealing element 33 melts or burns at a certain limiting temperature (eg 120 ° C.). Laser light then passes through the open through-hole 32 and loses itself in the rear triangle the lighting device.
The absorbent area can also be made by means of a multi-component injection molding process. The absorbent region may be made of: (a) an absorbent material which is resistant to the introduction of temperature by the laser light; or (b) an absorbent but non-temperature-resistant material, each with the effects already described above.
An injection molding process is most suitable for making a reflector in the context of the present invention. The use of a die casting method, in particular in combination with an injection molding method, is also conceivable in principle (for example, a reflector body with an opening in the die casting method and the closure element in an injection molding method could be produced).
With an embodiment according to FIG. 4, it is prevented that in the event of a fault laser light can escape from the headlight or the risk involved is reduced.
In the manufacture of a reflector body with an opening, in an injection molding process, a so-called "weld line" is produced, which under certain circumstances may be undesirable for aesthetic reasons; moreover, stray light can disadvantageously occur in the region of the boundary of the opening.
With the variant according to FIG. 3 (removal or non-application of the reflective coating), the problem of the weld line is also solved. Since no opening in the reflector body must be generated, no weld line can arise. The coating is usually very thin, typical values are in the range of 140 nm, so that the transition or the stage between the coated area and the uncoated area is irrelevant in terms of lighting technology, therefore no disadvantageous scattered light can arise there.
Such a disadvantageous scattered light does not arise in a correspondingly precise production even in an embodiment according to FIG. 4 in the region between the opening and the closure element.

权利要求:
Claims (15)
[1]
claims
1. lighting device (100), in particular for a motor vehicle, comprising: at least one laser light source (10); a wavelength conversion element (20) configured to receive excitation light from the at least one laser light source (10); and a reflector (30) having at least one reflector body (301), which at least one reflector body (301) comprises a reflection surface (31), which reflection surface (31) reflects the light emitted by the wavelength conversion element (20) in the visible wavelength range, the reflector (30) is provided with the reflection surface (31) on its reflector surface (30) carrying the reflection surface (31), characterized in that the reflector surface (30a) has at least one region (30a1, 30a ") which is free from the Reflection surface (31), and wherein the reflector surface (30a) at least in the region (30a1, 30a "), which is free from the reflection surface (31) is formed such that in the region (30a1, 30a") incident excitation Light is at least partially absorbed.
[2]
2. Lighting device according to claim 1, characterized in that the reflector surface (30a) is coated with a reflective material which forms the reflection surface (31).
[3]
3. Lighting device according to claim 2, characterized in that in the at least one region (30a1), which is free from the reflection surface (31), the reflector surface (30a) is not coated with the reflective material or the reflective material after coating in the at least one region (30a1) is removed, so that incident excitation light is at least partially absorbed at the reflector surface.
[4]
4. Lighting device according to one of claims 1 to 3, characterized in that the reflector body (301) has at least one passage opening (32), and wherein the at least one passage opening (32) with a closure element (33) is closed, wherein the surface ( 331) of the closure element (33) which lies on the side of the reflection surface (31) which forms the excitation light at least partially absorbing region (30a ").
[5]
5. Lighting device according to claim 4, characterized in that the surface (331) of the closure element (33) closes the passage opening (32) over its entire surface.
[6]
6. Lighting device according to claim 4 or 5, characterized in that the closure element (33) is formed and / or inserted into the passage opening (32) such that the surface (331) merges into the reflection surface (31) substantially continuously.
[7]
7. Lighting device according to one of claims 1 to 6, characterized in that the at least one excitation light absorbing region (30a1, 30a ") is formed such that the excitation light is largely or completely absorbed.
[8]
8. Lighting device according to one of claims 1 to 7, characterized in that the at least one absorbing region (30a1, 30a ") is formed temperature-resistant.
[9]
9. Lighting device according to one of claims 1 to 7, characterized in that the at least one absorbing region (30a1, 30a ") is not formed temperature-resistant above a limit temperature.
[10]
10. Lighting device according to claim 9, characterized in that the limit temperature is 120 ° C.
[11]
11. Lighting device according to one of claims 1 to 10, characterized in that an excitation light absorbing region (30a ', 30a ") is arranged in or on the reflector surface (30a) that directly from the laser light source (10 ) impinging on the reflector surface excitation light and / or excitation light, which is emitted from the conversion element (20), on the absorbing region (30a, 30a ") impinges.
[12]
12. Lighting device according to claim 11, characterized in that an absorbing region (30a ', 30a ") is arranged and designed with respect to its surface extension such that the entire directly from the laser light source (10) incident on the reflector surface excitation light and / or all the excitation light emitted from the conversion element (20) strikes the absorbing region (30a ', 30a ").
[13]
13. The lighting device according to claim 12, characterized in that an absorbing region (30a ', 30a ") is arranged and designed with respect to its surface extension such that the entire directly from the laser light source (10) incident on the reflector surface excitation light and / or the entire excitation light, which is emitted by the conversion element (20), exactly meets only the absorbing region (30a ', 30a ").
[14]
14. Motor vehicle headlight with at least one lighting device according to one of claims 1 to 13.
[15]
15. Motor vehicle with at least one lighting device according to one of claims 1 to 13 or with at least one motor vehicle headlight according to claim 14.

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法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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ATA50854/2014A|AT516554B1|2014-11-26|2014-11-26|Lighting device for a motor vehicle|ATA50854/2014A| AT516554B1|2014-11-26|2014-11-26|Lighting device for a motor vehicle|

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JP2017528169A| JP6517935B2|2014-11-26|2015-11-12|Lighting system for motor vehicles|

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US15/529,575| US10309605B2|2014-11-26|2015-11-12|Illumination apparatus for a motor vehicle|

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PCT/AT2015/050288| WO2016081967A1|2014-11-26|2015-11-12|Illumination apparatus for a motor vehicle|

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CN201580064480.0A| CN107076389A|2014-11-26|2015-11-12|Lighting device for motor vehicle|

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EP15808072.1A| EP3224085B1|2014-11-26|2015-11-12|Illumination apparatus for a motor vehicle|