EP2918898A1 - Illumination device for a vehicle - Google Patents

Abstract

The present invention relates to a lighting device for a vehicle having at least one light source (6) and at least one optical imaging element (2) arranged in the beam path of the light source (6), wherein a surface element (8) is arranged between the light source (6) and the imaging element (6) ), which is formed at least for illuminating the focal plane of the imaging element (2), wherein the light emitted by the light source (6) light is deflected via a reflector (7) to the surface element (8) and the reflector (7) in at least two spatial directions is movable mirror.

Description

The invention relates to a lighting device for a vehicle with at least one light source and at least one arranged in the beam path of the light source optical imaging element.

From the DE 10 2005 014 953 A1 is a motor vehicle with a lighting device with variable illumination volume known. This illumination device makes it possible for other road users to be recognized in the high beam range and for the areas of the high beam that would dazzle the detected participants to be omitted. As a result, a glare-free or adaptive main beam can be generated.

In addition, as shown in Fig. 1 a headlight 1 known, which is shown in a simplified representation. The headlight 1 has a lens 2 which is arranged on a roadway 5 for projection of the light emitted by a light-emitting diode array (LED array) 3 in advance of the vehicle. Through the lens 2, a projection image 4 of the activated LED array 3 is generated on the roadway 5.

Such LED arrays 3, which are located behind the lens 2 and whose arrangement is projected onto the road by the lens 2, on the one hand have the advantage that the individual light-emitting diodes do not have to be adapted to one another. However, the LEDs must have a relatively small edge length to illuminate different sectors on the roadway 5 can. LEDs with such an edge length offer little light output, so that the illumination for a high beam is insufficient.

In addition, LED modules are known to illuminate separate sectors in front of the vehicle. These LED modules require an optic that focuses the light very strongly. However, a large part of the LED light energy not used, because it can not be bundled. In addition, these modules must be very closely matched, which is extremely difficult and expensive.

Furthermore, light-emitting diodes with reflection optics are known, which can reduce the light without appreciable reduction of the light output, which however generate emission angles that are too coarse to be able to represent individual sectors on the road surface. Again, a complex adjustment of the optics is required, which is on the one hand costly and only up to a limited degree of accuracy possible.

Furthermore, the use of LCD (Liquid Crystal Display) and DMD (Digital Mirror Device) arrays is known, which have a low efficiency and thereby generate light outputs that are insufficient for the generation of a high beam of a headlamp for a vehicle.

From the DE 101 33 869 A1 a lighting device for a headlight of a motor vehicle is known, which has an array of punctiform electroluminescent light sources, such as laser diodes.

From the DE 10 2004 016 232 A1 Furthermore, in general, a white light-emitting device is known. The apparatus includes a laser diode and a phosphor layer positioned to receive light from the laser diode. The phosphor layer is adapted to absorb light from the laser diode and to emit light at longer wavelengths than the light of the laser diode.

It is an object of the present invention to provide a lighting device for a vehicle, with which the distribution of the light distribution for projection onto the roadway can be refined. In particular, a high light output is to be achieved with a low-consuming designed lighting device.

This object is achieved by a lighting device having the features of claim 1.

An illumination device according to the invention for a vehicle comprises at least one light source and at least one in the beam path of the light source arranged optical imaging element. Between the light source and imaging element, a surface element is arranged, which is formed at least for illuminating the focal plane of the imaging element. By such a configuration, a very fine distribution of the light distribution of the lighting device can be generated. It can be guaranteed a high light output. In addition, a relatively low adjustment effort is required for the components of the lighting device.

Preferably, the surface element for illuminating the focal plane is formed by light emission due to excitations of the material of the surface element by the light emitted by the light source. As a result, a high light output can be achieved by generating a peripheral illumination in the focal plane of the imaging optics.

Preferably, the surface element is designed for wavelength conversion of the light emitted by the light source. The illumination device preferably emits a light which appears white to the human eye. In particular, the surface element is thus materially composed such that the light emitted by the surface element appears white to the human eye. In this regard, the material composition of the surface element may be selected so that the light emitted by the light source is converted into a spectral range which, viewed individually or in superposition of the light rays, emits a white light.

If, in this connection, the light source is already designed to emit white light, then it is sufficient that the surface element is configured in a functionality merely for illuminating the focal plane of the imaging element. In particular, if the light source is not designed for the emission of white light and a corresponding spectral shift is to be made by the surface element, the surface element is preferably additionally formed with the functionality of the wavelength conversion.

Preferably, the light source is a laser, in particular a laser diode. In principle, therefore, only one laser as the light source suffices for the lighting device. However, it can be provided that several lasers are arranged. A laser light source allows a relatively small Energy consumption, so that in this regard an energy-efficient operation of the lighting device is possible. In addition, a compact and reduced-component design of the lighting device can be ensured thereby. A laser as a light source allows a very finely divided light distribution in the focal plane of the lens. LED arrays can not produce such a fine light distribution due to the reasons explained above, without losing light intensity. Lasers also have a smaller exit area than the area of a high-intensity LED, which is not designed as a laser diode.

Preferably, the surface element is substantially planar. By means of this embodiment, the illumination of the focal plane can be ensured particularly effectively and uniformly homogeneously at the respective desired locations.

It is particularly preferred if the surface element is arranged in the focal plane of the imaging element. This is the reason why the requirement for optimum illumination of the focal plane is fulfilled particularly advantageously.

Preferably, the surface element is formed of a material comprising a phosphor composition. In this regard, a suitable phosphor composition may be used, adapted to the wavelength of the light emitted by the light source. This is particularly true in view of the fact that the light emitted by the surface element appears white to the human eye. The excitation of the phosphor layer is preferably carried out with a laser. When converting the laser radiation into white light in the phosphor layer, the wavelength is flexible.

Preferably, the light emitted by the light source is deflected via a reflector to the surface element. The light emitted by the light source is thus not directly and directly emitted to the surface element, but it is a quasi indirectly and indirectly irradiated to the surface element. The reflector is preferably a mirror movable in at least two spatial directions. As a result, the deflection of the light beam emitted by the light source to the desired locations of the planar element can be achieved in a low-effort yet functionally reliable manner. Due to the advantageous embodiment of the micromirror with a two-dimensionally rotatable mounting can in this regard a highly flexible part be provided, with which the deflection of the light beam of the light source can be ensured quickly and at various positions of the surface element. As a result, depending on demand, very different figures can be generated and projected very quickly. Especially when using the lighting device in moving objects, the dazzling of other objects, in particular road users, can be prevented because quickly specific areas of the surface element can be irradiated or not illuminated. Preferably, the surface of the roller is shaped so that the length of the roller corresponds to at least the length or at least the width of the surface element. If the imaging element is subdivided into segments, the roller preferably consists of individual superimposed disks, which in their entirety restore the shape of a roller whose length corresponds at least to the length or at least the width of the surface element. The number of slices, the surface of which preferably can illuminate a column or row of the sheet element during a rotation, preferably corresponds to the number of segments in a column or row of the sheet element. In all embodiments, it is possible to reflect the light beam of the light source during a rotation of the roller on a row or column of the surface element. To cover the next columns or rows, the one-dimensionally movable reflector must direct the light beam to the next line of the roll or the next slice of the roll. This simplifies the two-dimensionally mounted reflector to a one-dimensional reflector and a rotating roller.

It can also be provided that a reflector unit has a reflector movable in a spatial direction and a rotatably mounted roller, which has a reflecting surface.

In particular, in this regard, a one-dimensionally rotatably mounted roller can be provided with a reflective surface. Preferably, the surface of the roller is shaped so that a column or a row of the surface element can be completely covered or illuminated with one rotation of the roller.

It can also be provided that the reflector is a sliding surface in a symmetry axis with a reflective surface. Here, the movable reflector completely eliminated, since the light source radiates directly onto the roller and the roller illuminates a row or column of the surface element. In order to illuminate further rows or columns of the surface element, the roller must be moved in the direction of its axis of rotation. Preferably, the surface of the roller is shaped such that a (virtual) disc of the roller directs the light beam of the light source to a different row or column of the surface element than the other (virtual) discs of the roller. In this way, a reflection unit is formed from a roller which rotates about the axis of rotation and which is displaceable in the direction of the axis of rotation. The rotation of the roller covers a row or column of the imaging element while the light source is stationary, while the displacement in the direction of the axis of rotation reaches the various columns or rows of the planar element.

In particular, by moving the reflector, the light can be deflected at a speed that can not be resolved by the human eye, whereby a projected overall image is perceived.

Preferably, the surface element is formed from a non-self-luminous material. A light emission of the surface element thus takes place only when an excitation of the material of the surface element has been carried out for light emission by the light of the light source. Unwanted light emissions or distortions of the light color can be prevented.

The surface element preferably has a plurality of defined surface segments defined from one another. This refinement allows a fine distribution of the light distribution on the projection surface, in particular the roadway, with many sectors or segments. This is particularly advantageous if different light functions are to be displayed or a light function is to be adapted individually to different environmental conditions. In particular, this is particularly advantageous in the glare-free adjustment of a high beam of a headlight of a vehicle. Especially with such a configuration, the dazzling of other road users can thus be avoided when the high beam function is set, since automatically controlled individual surface segments are not illuminated and thus not excited to emit light.

Preferably, the surface segments of the surface element are the same design and arranged in rows and columns. Preferably, this has Surface element thus a matrix-like configuration with surface segments.

In particular, the lighting device is designed as a headlight for apron illumination of a vehicle and for generating a high beam.

It can be provided that with the illumination device and the one light source, in particular a laser, the low-beam function can be additionally generated. It can also be provided that the low-beam function of the lighting device can be realized in the embodiment as a headlight by another separate light source. In this context, a not designed as a laser diode or an LED array could be provided.

Preferably, it is provided with the lighting device that the well-known in the art LED array (for example, the LED array in Fig. 1 ) is replaced by the trained on excitation for light emission surface element. As a result of the additional reflector, the light, which is preferably emitted by a laser, can be deflected depending on the situation in such a way that the laser beam scans the currently required light distribution on the surface element. This happens so fast that the scanning of the light distribution is not visible to the human eye.

In its preferred embodiment, the surface element also serves to generate white light from colored light, which is thus in the visible spectral range, or also in the invisible spectral range of the light source. This is then projected onto the road via the imaging optics, in particular at least one lens. A significant advantage in the use of a laser and a segmented surface element is that the halftone dots are significantly smaller than the edge lengths in conventional LED chips within an array, and thus a finer light distribution can be made possible. In addition, a plurality of light-emitting diodes in an array can be replaced by a single laser and preferably a reflector, in particular a mirror.

In principle, in addition to the already described light functions of the high beam and the low beam of a headlamp for a motor vehicle and the Realization of other lighting functions, such as cornering lights or daytime running lights, etc., are generated with the lighting device.

• Fig.1 eine schematische Darstellung einer aus dem Stand der Technik bekannten Beleuchtungsvorrichtung; und
• Fig. 2 eine schematische Darstellung einer erfindungsgemäßen Beleuchtungsvorrichtung.

An embodiment of the invention will be explained in more detail with reference to a schematic drawing. Show it:

• Fig.1 a schematic representation of a known from the prior art lighting device; and
• Fig. 2 a schematic representation of a lighting device according to the invention.

In the figures, identical or functionally identical elements are provided with the same reference numerals.

In Fig. 2 is a schematic representation of a lighting device realized as a headlight 1 'for a motor vehicle. In Fig. 2 only the components of the headlight 1 'which are sufficient for the understanding of the invention are shown. This can furthermore have a plurality of further components.

The headlight 1 'is thus designed for front-field illumination of the vehicle and designed in the exemplary embodiment, in particular with the procedure explained below and the components explained below for realizing the light function of the high beam. In particular, in this regard, a glare-free high beam is to be realized, which automatically controls controlled as a function of other road users different areas of the high beam, which would dazzle the identified participants. This provides a glare-free or adaptive high beam.

The headlight 1 'has at least one lens 2 as an optical imaging element. This lens 2 is positioned in the beam path of the laser 6 designed as a light source. In addition, in the embodiment shown in the focal plane of the lens 2, a planar surface element 8 is arranged, which has a multiplicity of surface segments 11 which are substantially identical in terms of shape design and dimensions. The light from parallel beams, which are not parallel to the optical axis of the lens 2, is collected in a plane behind the lens 2, which is just as far from the lens 2 is removed, like the focal point. This layer is called the focal plane.

The surface element 8 is arranged between the lens 2 and the laser 6 and designed to illuminate the focal plane of the lens 2. The surface element 8 is formed for illuminating the focal plane by light emission due to excitation of the material of the surface element 8 by the light emitted by the light source, the laser 6.

In addition, the surface element 8 is designed for wavelength conversion of the light emitted by the laser 6.

Between the laser 6 and the surface element 8, a reflector 7 is arranged, which is realized in the embodiment as a micromirror, which is movable in at least two spatial directions. As a result, the light 9 emitted by the laser 6 can be deflected and directed onto the surface element 8 as a reflected beam 10. As a result of the flexible mobility of the reflector 7, specific sectors or segments 11 of the surface element 8 can thus be irradiated and excited to emit light.

The material of the surface element 8 is adapted to the spectral range of the light 9 emitted by the laser 6 such that a conversion of the light takes place such that the light emitted by the surface element 8 appears white to the human eye. Preferably, the material of the sheet 8 is a phosphor composition.

Through the lens 2, the light emitted by the surface element 8 and appearing white to the human eye is projected onto the roadway 5, an image area 4 'with the grids of the projected segments 12 being represented in this respect. The surface element 8 thus serves firstly as a ground glass with respect to the orientation of the focal plane and secondly to the radiation conversion of the laser light, which may be in the red, green, blue or invisible to the human eye spectral range.

By segmenting the surface element 8, the radiating surface can be limited, which after the projection onto the roadway 5, the sectors or segments 12 of the glare-free high beam result. The deflection of the light beam 9 or 10 with the reflector 7 and thus the movement and scanning on the surface element 8 and the segments 11 takes place so fast that it is imperceptible to the human eye in the image area 4 'of the projection. The sectors or segments 12 projected on the roadway 5 as a function of the situation therefore appear as permanently homogeneously illuminated areas.

The headlight 1 'as shown in FIG Fig. 2 Thus, for the illustrated high beam functionality, no LED array as shown in FIG Fig. 1 more on. This LED array 3 is replaced by the surface element 8.

The surface element 8 is also formed of a material which is itself non-luminous. This means that no light emission takes place without excitation of the material of the surface element 8 by the light of the light source.

Claims (12)

Lighting device for a vehicle with at least one light source (6) and at least one in the beam path of the light source (6) arranged optical imaging element (2), wherein between the light source (6) and the imaging element (2) a surface element (8) is arranged, which is formed at least for illuminating the focal plane of the imaging element (2),
characterized in that
the light emitted by the light source (6) is deflected via a reflector (7) to the surface element (8) and the reflector (7) is a mirror movable in at least two spatial directions. Lighting device according to claim 1,
characterized in that
the surface element (8) for illuminating the focal plane is formed by light emission due to excitation of the material of the surface element (8) by the light emitted by the light source (6). Lighting device according to claim 1 or 2,
characterized in that
the surface element (8) is designed for wavelength conversion of the light emitted by the light source (6). Lighting device according to one of the preceding claims,
characterized in that
the light source (6) is a laser, in particular a laser diode. Lighting device according to one of the preceding claims,
characterized in that
the surface element (8) is substantially planar. Lighting device according to one of the preceding claims,
characterized in that
the surface element (8) is formed from a material comprising a phosphor composition. Lighting device according to one of the claims 1,
characterized in that
by moving the reflector (7), the light can be deflected in a speed that can not be resolved by the human eye. Lighting device according to one of the preceding claims,
characterized in that
the surface element (8) is formed from a non-self-luminous material. Lighting device according to one of the preceding claims,
characterized in that
the surface element has a plurality of defined limited surface segments (11). Lighting device according to claim 9,
characterized in that
the surface segments (11) are identical and are arranged in rows and columns. Lighting device according to one of the preceding claims, which is designed as a headlight (1 ') for apron illumination of a vehicle and for generating the high beam. Lighting device according to one of the preceding claims,
characterized in that
the surface element (8) is arranged in the focal plane of the imaging element (2).

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