DE102012100141A1 - Light module for headlight of vehicle, has deflection element that is arranged in optical path formed between beam source and converter element, so that deflection element is spatially arranged between converter and beam-forming elements - Google Patents

Abstract

The light module (1) has a laser beam source (10) to irradiate a laser beam (12) with respect to a converter element (11). The light (13) with flash spectrum qualified for vehicle lighting is radiated from the converter element into one beam forming element (14,19). One beam deflection element (15-18) is arranged in an optical path formed between the laser beam source and the converter element to deflect the laser beam, such that the beam deflection element is spatially arranged between the converter element and the beam-forming element. An independent claim is included for a headlight.

Description

The present invention relates to a light module, in particular for a headlamp or a lamp of a vehicle, having at least one laser beam source and at least one converter element which can be irradiated by the laser beam source with a laser beam, whereby light with a qualified for a vehicle lighting light spectrum through the converter element in at least one beam-shaping element can be emitted.

STATE OF THE ART

From the US 2011/0141754 A1 For example, a light module for the headlamp of a vehicle is known, and there is shown a laser beam source which can selectively irradiate various converter elements via an optical switch. Each of the converter elements is followed by beam-forming elements in order to produce a particularly variable light spectrum qualified for vehicle lighting.

Disadvantageously, the backside arrangement of the laser beam source behind the converter elements results in a space-consuming arrangement for forming the light module. In this case, only the arrangement of the optical elements is shown schematically on the converter elements, which are referred to as phosphor elements. The optical elements can be formed, for example, by beam-shaping elements such as reflectors or lenses, so that at least part of the beam path of the light radiation extends from the phosphor elements to the associated limes or reflectors.

In order to make the light module smaller, in particular in order to create a compact light module, it would be desirable to arrange the laser beam source between the phosphor element and the beam-shaping element. Disadvantageously, however, the arrangement of the laser beam source disturbs the beam path between the phosphor element and the beam-shaping element such as the lens or the reflector.

Furthermore, there is the disadvantage that a laser beam, as can be generated by commercially available laser beam sources, for example of diode lasers, has a small diameter with a correspondingly high intensity. If the phosphor element is irradiated with a laser beam of small diameter, an unfavorable emission characteristic of the light distribution of the converter element can result. Although generally beam-shaping elements, for example, for expanding and homogenizing a laser beam are known, but these can also be arranged only with a corresponding disadvantage between the laser beam source and the converter element.

DISCLOSURE OF THE INVENTION

It is therefore the object of the present invention to provide a light module, in particular for a headlight of a vehicle, which overcomes the aforementioned disadvantages of the prior art. In particular, the object is to provide a compact light module with at least one laser beam source, which can generate a qualified light for a vehicle lighting spectrum.

This object is achieved on the basis of a light module according to the preamble of claim 1 in conjunction with the characterizing features. Advantageous developments are specified in the dependent claims.

The invention includes the technical teaching that at least one beam deflection element for deflecting the laser beam is arranged in the beam path between the laser beam source and the converter element, wherein the beam deflection element is arranged spatially between the converter element and the beam-shaping element.

The invention uses the advantageous idea to arrange a beam deflection element between the laser beam source and the converter element. In this case, the converter element is illuminated from the same side with the laser beam, in which the converter element radiates the qualified for the vehicle lighting light spectrum in the direction of the beam-shaping element. By the irradiation and the radiation of the converter element from a common side of the converter element, a significantly smaller space can be implemented for the complete formation of a light module, since the laser beam source does not have to be arranged behind the converter element to activate the converter element in the transmission method. This avoids that the converter element is irradiated from a first side with a laser beam, and emits from a second side the qualified for the vehicle lighting spectrum of light. However, it is also avoided that the laser beam source between the converter element and the beam-forming element must be arranged.

According to the converter element in shape and / or surface and / or texture is formed such that the light emits in the manner of a Lambertian radiator from the converter element, in particular, the beam-forming element can thus be irradiated surface. Preferably, the qualified for vehicle lighting light spectrum radiates from the converter element from, and despite a directed irradiation of the converter element with a laser beam radiates the converter element in all directions. The light spectrum qualified for the vehicle lighting comprises at least partially the length of the laser radiation, for example 480 nm, and the wavelength spectrum is expanded by the converter element to, for example, up to 780 nanometers. Thus, the light spectrum provided by the converter element appears as white light, the laser beam source irradiating the converter element with blue light.

According to an advantageous embodiment, the beam deflecting element can be movable in particular by a movement system. Preferably, a plurality of beam deflection elements can be provided, which are movable by one or more associated movement systems. For example, a plurality of array or arrayed arranged converter elements may be provided which can be selectively irradiated by the laser beam, and the motion system, for example, as a scanner system highly dynamic, but advantageously slowly moves how a current cornering light with significantly reduced dynamics, accuracy and control requirements are performed , It is also conceivable to direct the laser beam of one or more laser beam sources to different converter elements in which the beam deflection element is moved accordingly by the movement system. Thus, for example, dipped beam, high beam or highway light functions can be realized. In this case, each converter element can be assigned one or more laser beam sources.

The movement system may preferably be executed only partially dynamic, and it may, for example, movements of the beam deflecting element with only, for example, up to 15 ° / sec. be reached around a movement axis. It is also conceivable to direct the laser beam of one or more laser beam sources to different converter elements in which the beam deflection element is moved accordingly by the movement system. Thus, for example, dipped beam, high beam or highway light functions can be realized. In this case, each converter element can be assigned one or more laser beam sources.

According to a further advantageous embodiment, the converter element can have an elongated or planar extension, wherein the laser beam can be guided by a movement of the beam deflection element, in particular by means of the movement system along the elongate extension or on the surface via the converter element. As a result of the movement of the beam deflection element, the light center of gravity on the converter element can thus be carried out in a mobile manner. The light spectrum radiating from the converter element can be regarded as a pseudo-light source which irradiates the beam-shaping element, for example a reflector or a lens. If the location of the pseudo-light source is wandering, then a corresponding function changing the emitted light can be realized. For example, a curve light function can be implemented, or the movement of the center of gravity on the converter element allows the function of an adaptive cut-off or a marking light.

With special advantage, the beam deflection element can be arranged on the beam-forming element itself. Thus, the beam deflecting element can be held or received by the beam-shaping element. The beam deflection element can be formed, for example, by a mirror, in particular by a plane mirror, by a concave mirror, by a convexly shaped mirror or at least one prism element. Due to the small diameter of the laser beam, which is generated by the laser beam source, the beam deflecting element can also be made correspondingly small. Due to the comparatively small design of the beam deflection element compared to the dimension of the beam-shaping element, for example the reflector and / or the lens, the beam path of the light spectrum qualified for the vehicle lighting is not significantly affected. The arrangement of the beam deflecting element on the beam-shaping element is preferably carried out in a rigid design and may be provided for light modules, which are not designed with a movement system of the beam deflecting element. In the present case, the arrangement of the beam deflecting element on the beam-shaping element is understood as an arrangement of the beam deflecting element between the converter element and the beam-shaping element.

With further advantage, the beam deflection element can be designed such that the laser beam is widened when it leaves the beam deflection element again. The expansion can preferably be provided such that the irradiable surface of the converter element is at least predominantly irradiated by the expanded laser beam surface. The expansion can be carried out horizontally and vertically with a different reflector strategy or as a free-form surface.

In particular, the beam deflection element can be designed such that the irradiation of the converter element takes place with an intensity gradient. Target with the light module Low beam are generated, it is desirable to provide an intensity gradient having an intensity maximum on the underside adjacent to the cut-off line, and the intensity of the light field drops as it approaches the apron in front of the headlights accordingly. In order to improve the contrast of a light-dark boundary already by the irradiation of the converter element with an intensity gradient, an absorber body can be arranged on the converter element, which forms in particular an absorber edge to the converter element. The absorber edge can, for example, have the contour of the cut-off line which is projected by the beam-shaping element, for example by a lens, in front of the headlights. For example, the absorber body may be designed as a beam deflecting body to direct a portion of the radiation in a jet trap. Thus, a high contrast of the cut-off line can be achieved without requiring a further diaphragm element in the beam path between the converter body and the beam-shaping element, for example a projection lens.

According to a further embodiment, the beam deflection element may be formed by a concave mirror, and the concave mirror may preferably be arranged on the beam-shaping element and may even be formed by a part of the beam-shaping element itself. For example, the beam-shaping element may be a plastic lens, which has on a plan side the concave mirror, which is made of the same material with a plano-convex lens. In particular, by a concave mirror, a widening of the laser beam can be generated in order to irradiate the converter element areally. Also, the expansion of the laser beam can be generated by a convex mirror, which can also be arranged on the plan side of a plano-convex lens of the light module.

In an advantageous development of the mirror is designed as a free-form mirror, whereby intensity gradients largely free expression can be generated on the converter element. These intensity gradients are e.g. maximum near the low-beam light-dark boundary and flat to the apron of the low beam distribution or to the side of the road illumination down. By a modulation of the mirror surface, a high homogeneity can be generated.

The invention further relates to a headlamp with a light module comprising at least one laser beam source and at least one converter element which can be irradiated by the laser beam source with a laser beam, with which light with a light spectrum qualified for vehicle illumination can be emitted by the converter element into at least one beam-shaping element, wherein at least one beam deflection element for deflecting the laser beam is arranged in the beam path between the laser beam source and the converter element, and wherein the beam deflection element is arranged spatially between the converter element and the beam-shaping element. The features and advantages of the light module described above are also usable and achievable for a headlamp with a similar light module.

PREFERRED EMBODIMENTS OF THE INVENTION

Next, the invention improving measures are shown below together with the description of preferred embodiments of the invention with reference to the figures. It shows:

1 An embodiment of a light module with a plane mirror, which is arranged on a lens,

2 an embodiment of the light module with a convex-shaped mirror on the plan side of the lens,

3 an embodiment of the light module with concave mirror and upstream laser beam expansion,

4 an embodiment of the light module with a convex-shaped mirror which is movably arranged,

5 An embodiment of the light module with two convex mirrors and laterally arranged laser beam sources,

6 a further embodiment of the light module according to 5 with laser beam sources, which are arranged together with a converter element on a heat sink,

7 An embodiment of the light module with a beam deflection element which is movable with a movement system in two axes and a large-area converter element,

8th an embodiment of the light module with a beam redirecting element, which is designed as a prism element and

9 An embodiment of a light module with a movable beam deflection element and a beam-forming element, which is designed as a reflector.

1 shows a first embodiment of a light module 1 with the features of the present invention. On a heat sink 23 there is a laser beam source 10 for emitting a laser beam 12 which may, for example, have a wavelength of 480 nm. A heat sink 24 , the exemplary one-piece with the heat sink 23 is listed, takes a converter element 11 on, which may for example consist of a phosphorus leaflet. In the beam path of the laser beam 12 between the laser beam source 10 and the converter element 11 is a beam deflecting element 15 arranged. The beam deflecting element 15 is exemplary as a plane mirror 16 executed and reflected the laser beam 12 towards the converter element 11 , The laser beam source 10 emits the laser beam 12 while first in the direction of the lens 19 and through the plane mirror 16 becomes the laser beam 12 towards the converter element 11 diverted.

The Lens 19 forms a beam-shaping element 14 , and is designed as a plano-convex lens. By the irradiation of the converter element 11 is emitted for a vehicle lighting qualified light spectrum that as light 13 is designated. This forms the converter element 11 a pseudo-light source and that of the converter element 11 essentially white light emitted in the manner of a Lambertian emitter 13 is through the lens 19 in front of the light module 1 projected.

That as approximate as a plane mirror 16 executed beam deflection element 15 acts in combination with the laser beam source while slightly diverging, so that the laser beam 12 the converter element 11 irradiated essentially flat. The heat sink 23 has not shown in detail at the receiving point of the converter element 11 an edge acting as an absorber body 21 acts. The plane mirror can do this 16 be shaped such that the converter element 11 with an intensity gradient through the laser beam 12 is irradiated. The intensity can be at the absorber edge of the absorber body 21 have a maximum, and by the absorbing action of the absorber body 21 creates a high contrast of a cut-off line through the lens 19 in front of the light module 1 can be projected. Thus, on the one hand by the gradient of the intensity, which is generated by a corresponding shape of the mirror 16 , and additionally through the absorber body 21 a light-dark boundary are formed without further diaphragm elements to form a light module 1 are required for a low beam. Alternatively, a possible homogeneous illumination of the converter element can be sought. In addition to low beam, marking light or motorway light, the module can be used as a cornering example as an example.

2 shows a further embodiment of a light module 1 with a laser beam source 10 for emitting a laser beam 12 , Shown is a beam-shaping element 14 as a lens 19 is executed with a plane surface. On the plane surface of the lens 19 there is a beam deflecting element 15 as a convex shaped mirror 17 is executed. In this case, a beam widening for illumination of the converter element 11 shown by the convex shaped mirror 17 in the laser beam 12 is caused. The converter element 11 Can be centered in front of the lens 19 be arranged, and that of the converter element 11 provided light 13 comes in front of the light module 1 projected. By way of example, the light module 1 be executed as a high beam module and the intensity of the expanded laser beam for irradiation of the converter element 11 may have a substantially homogenized intensity, and the converter element 11 For example, does not have an absorber body.

3 shows a further construction of a light module 1 with the features of the present invention. With a laser beam source 10 becomes a laser beam 12 provided, the first a beam shaping element 25 passes. The beam shaping element 25 causes a first expansion of the laser beam 12 before this on a concave mirror 18 which hits in turn on the plan side of a lens 19 is arranged. The through the concave mirror 18 reflected laser beam irradiates a converter element 11 flat, whereby the converter element 11 the light 13 towards the lens 19 sending out. That as a concave mirror 18 executed beam deflection element 15 is exemplary one piece with the lens 19 executed, which may be made of a plastic material or a glass material, for example, and the concave mirror 18 is formed on the flat surface of the plastic lens. The concave mirror can also be further developed by a free-form mirror.

4 shows a light module 1 with a movable beam deflecting element 15 , This is exemplary as a convex shaped mirror 17 executed and can be pivoted about at least one axis. The laser beam source 10 sends a laser beam 12 from, the first a laser beam forming element 25 goes through and is widened by this. The expanded laser beam 12 illuminates the convex shaped mirror 17 that the laser beam 12 further expands to a converter element 11 to be irradiated flat in a sub-segment with a flat extension. Will the beam deflecting element 15 , For example, moves in the direction of the double arrow shown, so the light center moves on the converter element 11 also. The center of gravity on the converter element 11 forms thereby the pseudo light source, the light 13 towards the lens 19 sending out. For example, with a movement of a very small element, such as a small mirror 17 , a cornering function of the light module 1 be provided without the light module 1 itself must be moved consuming within a headlight. The concave mirror 17 can be further developed as an example by a Freuformspiegel.

5 shows an embodiment of a light module 1 with two beam deflection elements 15 , each with a laser beam 12 be irradiated. The beam deflection elements 15 are shaped so that the laser beam 12 through the deflection elements 15 is widened to a planar irradiation of the converter element 11 through both laser sources 10 to reach. By the irradiation of the converter element 11 can light towards the lens 19 be emitted, which is the beam-shaping element 14 forms.

6 shows a further arrangement with at least two laser beam sources 10 of which two are shown and one converter element 11 , and the laser sources 10 are on a heat sink 23 and the converter element 11 is on a heat sink 24 shown, the heat sink 23 and 24 are made in one piece with each other. The laser sources 10 send a laser beam 12 in the direction of at least two steel deflecting elements 15 from, which are designed as a plane mirror. These can in turn be a converter element 11 irradiate to light towards the lens 19 to generate the beam-shaping element 14 of the light module 1 forms. The laser beams run thereby 12 initially orthogonal to the plane surface of the lens 19 to, and the plane mirror 16 are arranged such that the laser beams 12 obliquely towards the converter element 11 be redirected.

7 shows in a perspective view a light module 1 with a laser beam source 10 a laser beam forming element 25 and a beam redirecting element 15 , the example as a free-form mirror 16 is executed. The one with the laser beam source 10 provided laser beam 12 is first through the laser beam forming element 25 slightly widened and irradiated the freeform mirror 16 , This is connected in a manner not shown in detail with a movement system, so that the free-form mirror 16 can be pivoted by two axes as an example. Due to the pivoting of the free-form mirror 16 can the laser beam 12 for illumination of the converter element 11 be changed in his position. The converter element 11 is designed with a flat extension, and the laser beam 12 can over the area of the converter element 11 hike. As a result, the focus of light shifts on the converter element 11 , and thus the pseudo-light source also emigrates to illuminate the lens 19 , This creates the effect that the light 13 that of the converter element 11 is provided, the lens 19 also illuminates spatially, so with this light module 1 in turn, a cornering light function, for example, an adaptive dipped beam, a headlight range control movement, a marking light or other adjustment of the light 13 arises. The with the plane mirror 16 Reflected laser light can be the converter element 11 in turn illuminate with an intensity gradient with optically generated, optional cut-off, and the intensity gradient can through the lens 19 in front of the light module 1 be projected.

8th shows a further construction of a light module 1 with a laser beam source 10 and a laser beam shaping element 25 , This is followed by a beam deflection element 15 on, as a prism element 22 is trained. In this case, the laser beam over the curved surface in the prism element 22 enter and over the plane surface of the prism element 22 exit again. The light is directed in the direction of the prism base, wherein the height of the corresponding optically effective prism base and thus the angular deflection are variable and therefore depend on the angle of the prism element. By a movement of the prism element 22 in the direction shown the double arrow shown, the laser beam 12 via the likewise flat converter element 11 wander, allowing a movement of light 13 This is made possible by the lens 19 in front of the light module 1 is projected.

Finally shows 9 an embodiment of a light module 1 with a laser beam source 10 that exemplifies a heat sink 23 is cooled. The laser beam source 10 represents a laser beam 12 ready, the one as a plane mirror 16 executed beam deflection element 15 irradiated. The plane mirror 16 is about a vertical axis 26 swiveling so that the laser beam 12 the converter element 11 can irradiate mobile. This is the converter element 11 designed with an elongated, arcuate extension and on a heat sink 24 arranged. Will the plane mirror 16 around the vertical axis 26 twisted, so the light spot on the converter element 11 along the elongated extension of the converter element 11 hike. Through the converter element 11 becomes the center of gravity of the laser beam 12 light 13 generated in the direction of a beam-shaping element 14 shine. The beam-shaping element 14 is as a reflector 20 executed, which in a manner not shown in detail, a shape, in particular a freeform, may own, so that the light 13 the reflector 20 can also illuminate portable. Thus, even with a beam-shaping element 14 as a reflector 20 is executed, a movable light function of the light module 1 be generated, for example, to fulfill a cornering function and / or an adaptive dimming function, a marking light and / or an adjustment function.

The invention is not limited in its execution to the above-mentioned preferred embodiment. Rather, a number of variants is conceivable, which makes use of the illustrated solution even with fundamentally different types of use. Any features and / or advantages resulting from the claims, the description or the drawings, including constructional details or spatial arrangements, can be essential to the invention, both individually and in the most diverse combinations.

LIST OF REFERENCE NUMBERS

1

 light module

10

 laser beam source

11

 converter element

12

 laser beam

13

 light

14

 beam-shaping element

15

 Beam deflecting element, mirror

16

 Plane mirror, free-form mirror

17

 convex shaped mirror

18

 concave mirror

19

 lens

20

 reflector

21

 absorber body

22

 prism member

23

 Heat sink (for laser beam source)

24

 Heat sink (for converter element)

25

 Laser beam shaping element

26

 vertical axis

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

• US 2011/0141754 A1 [0002]

Claims (12)

Light module ( 1 ), in particular for a headlight or a lamp of a vehicle, with at least one laser beam source ( 10 ) and at least one converter element ( 11 ) generated by the laser beam source ( 10 ) with a laser beam ( 12 ) is irradiated, whereby light ( 13 ) with a light spectrum qualified for vehicle lighting by the converter element ( 11 ) in at least one beam-shaping element ( 14 . 19 . 20 ) is radiatable, characterized in that in the beam path between the laser beam source ( 10 ) and the converter element ( 11 ) at least one beam deflecting element ( 15 . 16 . 17 . 18 . 22 ) for deflecting the laser beam ( 12 ), wherein the beam deflecting element ( 15 . 16 . 17 . 18 . 22 ) spatially between the converter element ( 11 ) and the beam-shaping element ( 14 . 19 . 20 ) is arranged. Light module ( 1 ) according to claim 1, characterized in that the converter element ( 11 ) is formed in the form and / or surface and / or condition such that the light ( 13 ) in the manner of a Lambertian radiator from the converter element ( 11 ), in particular that the beam-shaping element ( 14 . 19 . 20 ) is extensively irradiated. Light module ( 1 ) according to claim 1 or 2, characterized in that the beam deflecting element ( 15 . 16 . 17 . 18 . 22 ) is movable in particular by a movement system. Light module ( 1 ) according to one of claims 1 to 3, characterized in that the converter element ( 11 ) has an elongated or planar extension, wherein the laser beam ( 12 ) by a movement of the beam deflecting element ( 15 . 16 . 17 . 18 . 22 ) along the elongate extension or on a surface via the converter element ( 11 ) is feasible. Light module ( 1 ) according to one of claims 1, 2 and 4, characterized in that the beam deflecting element ( 15 . 16 . 17 . 18 ) at the beam-shaping element ( 14 . 19 . 20 ) and in particular by the beam-shaping element ( 14 . 19 . 20 ) is held. Light module ( 1 ) according to one of the preceding claims, characterized in that the beam deflecting element ( 15 . 16 . 17 . 22 ) through a mirror ( 15 ) is formed, in particular by a concave mirror ( 16 ), by a divergence mirror, by a convex-shaped mirror ( 17 ) and / or by at least one prism element ( 22 ). Light module ( 1 ) according to one of the preceding claims, characterized in that the beam deflecting element ( 15 . 16 . 17 . 18 ) is such that the laser beam ( 12 ) is expanded, preferably such that the irradiable surface of the converter element ( 11 ) at least predominantly by the expanded laser beam ( 12 ) is irradiated flat, in particular irradiated with an intensity gradient. Light module ( 1 ) according to one of the preceding claims, characterized in that the beam deflecting element ( 15 . 18 ) by a concave mirror ( 18 ), wherein the concave mirror ( 18 ) preferably on the beam-shaping element ( 14 . 19 . 20 ) and in particular by a part of the beam-shaping element ( 14 . 19 . 20 ) is formed. Light module ( 1 ) according to one of the preceding claims, characterized in that the beam-shaping element ( 14 . 19 . 20 ) through a lens ( 19 ) and / or by a reflector ( 20 ) is formed. Light module ( 1 ) according to one of the preceding claims, characterized in that on the converter element ( 11 ) an absorber body ( 21 ) is arranged, in particular an absorber edge to the converter element ( 11 ). Headlamp with a light module ( 1 ) comprising at least one laser beam source ( 10 ) and at least one converter element ( 11 ) generated by the laser beam source ( 10 ) with a laser beam ( 12 ) is irradiated, whereby light ( 13 ) with a light spectrum qualified for vehicle lighting by the converter element ( 11 ) in at least one beam-shaping element ( 14 . 19 . 20 ) is radiatable, characterized in that in the beam path between the laser beam source ( 10 ) and the converter element ( 11 ) at least one beam deflecting element ( 15 . 16 . 17 . 18 . 22 ) for deflecting the laser beam ( 12 ), wherein the beam deflecting element ( 15 . 16 . 17 . 18 . 22 ) spatially between the converter element ( 11 ) and the beam-shaping element ( 14 . 19 . 20 ) is arranged. Headlamp according to claim 11 with a light module ( 1 ) according to any one of claims 2 to 10.

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