The invention relates to a lighting device for a motor vehicle headlight, wherein the lighting device comprises at least one optical body and at least one mounting device for the least one optical body, wherein the at least one optical body has a number of adjacently arranged ancillary optics, wherein each ancillary optics is formed from a light-guiding material and each ancillary optics has a light-coupling face and a light-decoupling face, wherein the at least one mounting device has at least one receptacle for each ancillary optics, and wherein receptacles are delimited by delimiting walls, wherein the delimiting walls have boundary edges on the light exit side, which boundary edges are imaged, in a light distribution produced by means of the at least one optical body, as light-dark edges between the partial light distributions produced by the individual ancillary optics, and wherein a projection arrangement, preferably a projection lens, is arranged downstream of the least one optical body in the light exit direction.
The invention also relates to a light module for a motor vehicle headlight, comprising at least one such lighting device.
In addition, the invention also relates to a motor vehicle headlight comprising one or more light modules of this type.
Optical bodies of the type mentioned in the introduction are used in light modules for motor vehicle headlights in order to produce light distributions, for example in order to produce segmented lights distributions, i.e. light distributions which are constructed from individual light segments. The ancillary optics are generally manufactured from plastic, silicone, glass, etc. In order to meet the requirements in terms of light, i.e. in particular the legal stipulations and the stipulations of car manufacturers, and also in order to withstand the mechanical stresses for as long as possible, preferably over the service life of the vehicle, it is necessary for the optical bodies to be fixed accurately and in a stable manner in this desired position.
In order to define the individual light segments it is necessary to delimit these relatively sharply, in particular laterally. For this purpose, the individual ancillary optics of the optical body are delimited at least laterally by delimiting walls, wherein these delimiting walls are formed from a light-impermeable material.
The light-decoupling faces of the ancillary optics and the light exit-side boundary edges of the delimiting walls lie in a common plane, wherein this plane can be flat or curved. The focal point of a projection lens arranged downstream of the optical body, which projection lens images the light distribution into a region in front of the vehicle, lies here in this common plane, such that the boundary edges of the delimiting walls are imaged as sharply as necessary in the light pattern and the light segments are therefore sharply delimited accordingly.
However, it has been found that dust deposits often form on the light exit faces of the ancillary optics, which dust deposits are visible in the light distribution or in the individual light segments as dark flecks and disturb the homogeneity of the light distribution or the light segments, which is undesirable.
The object of the invention is to overcome this problem.
This object is achieved with an ancillary optics system as mentioned in the introduction in that, in accordance with the invention, the ancillary optics are arranged and/or configured in such a way that the light-decoupling faces of the ancillary optics protrude beyond the boundary edges of the delimiting walls in the light exit direction.
Due to the protruding arrangement of the light-decoupling faces with respect to the boundary edges, the boundary edges, which are still arranged in a plane containing the focal point of the downstream projection lens, are still imaged sharply, whereas the light-decoupling faces are imaged in a defocussed manner and accordingly are imaged in a blurred manner. For the light distribution within the individual light segments, this blurred imaging is irrelevant, since a homogeneous light distribution is what matters here, whereas the delimitation of the light segments is still imaged sharply. Due to the defocussing of the light-decoupling faces, however, any dust deposits are also imaged in a defocussed manner and accordingly can no longer be identified and no longer disturb the homogeneity of the light distribution.
As already mentioned above, the boundary edges lie in a common plane, wherein this plane is preferably continuous, in particular at least C0 continuous.
The common plane of the boundary edges is typically flat and is preferably arranged approximately normal to the light exit direction.
The light-decoupling faces are curved and/or are arranged along a curved bend, for example in order to follow a field of view curvature of the lens. However, the light-decoupling faces of the ancillary optics are preferably flat.
It is also preferable when the light-decoupling faces of the ancillary optics lie in a common plane.
It is also advantageous when the common plane of the light-decoupling faces is arranged at a constant distance from the common plane of the boundary edges.
The light-decoupling faces are therefore arranged throughout at the same normal distance from the plane through the boundary edges of the delimiting walls, and therefore extend in parallel.
As also already mentioned above, it is advantageous when the common plane of the boundary edges lies in a focal point of the projection lens or contains this. In this way, the boundary edges are imaged sharply in the light pattern.
Is also expedient when the ancillary optics bear directly, i.e. with no distance, against the delimiting walls of their at least one receptacle so as to obtain an optimal optical display of the light segments.
Here, delimiting walls are provided at least between the adjacently arranged receptacles.
However, it is particularly preferred when the two outer receptacles are also each delimited at their outer side by delimiting walls.
In accordance with a specific embodiment of the invention adjacently arranged receptacles are separated in each case by a common separation web, which webs form the delimiting walls for the adjacent receptacles.
In order to fasten the least one optical body in the desired position relative to light sources, which feed light to the ancillary optics, the mounting device for the optical body can be connected to a support for the one or more light sources, which is/are provided in order to radiate light into the ancillary optics of the optical body.
In a specific embodiment of the invention relevant in practice, the position of the boundary edges relative to the at least one light source is fixed, and the optical body is lengthened in the light exit direction compared with an optical body of which the light exit faces lie in a common plane with the boundary edges.
The effects according to the invention can thus be achieved even in existing support-mounting device systems merely by modification of the optical body.
In accordance with a specific embodiment the mounting device comprises a main body, which can be connected to the support for the one or more light sources for feeding light into the optical body.
The receptacles for the ancillary optics are then preferably formed in the main body.
The optical body is held in the main body by means of a retaining body, which presses the optical body into the main body formed suitably for this purpose and holds the optical body in the desired position in a stable manner following connection of the retaining body to the main body.
In accordance with a specific embodiment of the invention the ancillary optics are mechanically interconnected in the region of the light-decoupling faces by means of at least one connecting web extending transversely to the ancillary optics, wherein the at least one connecting web is optically ineffective at least in regions, and wherein the main body also has at least one stop region, against which the optical body can be brought into abutment via a rear face of the at least one connecting web when the ancillary optics are inserted into the at least one receptacle.
In order to produce a segmented light distribution, it is advantageous when the light-decoupling faces of adjacent ancillary optics are arranged at a distance a>0 from one another.
For manufacturing reasons it may also be advantageous if the optical body consists of at least two separate optical components, wherein each optical component comprises at least one light-guiding body.
It is particularly expedient if the optical element consists of precisely two optical components, wherein it is then preferable if at least one, preferably all optical components comprises/comprise two or more light-guiding bodies.
The invention will be explained in greater detail hereinafter on the basis of the drawing, in which
The light-decoupling faces 11b-15b of adjacent ancillary optics 11-15 here are arranged at a distance a>0 from one another, and, as illustrated, adjacent ancillary optics are generally distanced from one another over their entire extent and not only in the region of the light-decoupling faces in order to prevent a passing of light from one ancillary optics into an adjacent ancillary optics.
The ancillary optics 11-15 are mechanically interconnected in the region of the light-decoupling faces 11b-15b by two connecting webs 21, 22 extending transversely to the ancillary optics 11-15. These connecting webs 21, 22 are usually optically ineffective here, at least in regions. The connecting webs 21, 22 are disposed here in the installed position of the optical body (i.e. of the light module or headlight containing the optical body in question) one in an upper and one in a lower region of the optical element 1.
The optical body or the optical element 1 can be manufactured from one piece. For manufacturing reasons, however, it may be particularly advantageous if the optical body 1 consists as shown of two separate optical components 1a, 1b, wherein each optical component 1a, 1b comprises two or more ancillary optics 11, 13, 15; 12, 14 (in the specific example two and three ancillary optics).
It should be noted at this juncture that the invention is not limited to an optical body as illustrated in the figure, although the use of an optical body of this type is preferred. Instead, the invention also extends by way of example to a one-part optical body, and also to optical bodies, in which the ancillary optics are not mechanically interconnected by means of one or more transverse webs.
The mounting device 100 in the shown example has a main body 101 and a retaining body 102, which, following the introduction of the optical body 1 into the main body 101, can be applied to the main body 101 in the direction of introduction of the optical body 1 (i.e. substantially against the light exit direction) and can be fastened thereto. A fastening device 101a, 102a is also provided, by means of which the retaining body 102 can be fixed to the main body 101.
In the shown example the fastening device comprises detent elements 102a and corresponding detent recesses 101a, wherein the detent elements 102a are arranged on the retaining body 102 and the corresponding detent recesses 101a are arranged on the main body 101. The main body and retaining body can in this way be connected to one another in a stable manner, such that the ancillary optics is also held in a stable manner in the desired position.
As can be inferred from
The retaining body 102 has clamping elements 102b which, when the retaining body 102 is fastened to the main body 101, come to rest against the connecting webs 21, 22 on the front faces thereof and press the optical body 1 via the transverse webs 21, 22 thereof against stops 121, 122 in the main body 101.
Furthermore, the retaining body 102 has clamping elements 102c, which, when the retaining body 102 is fastened to the main body 101, come to rest against one or more light-decoupling faces or preferably, as shown, in a region of the light-decoupling faces 11b-15b of the ancillary optics 11-15.
The clamping elements 102b, 102c press the optical body 1 against the stop regions 121, 122 of the main body 101, for which purpose the clamping elements 102b, 102c are preferably resilient, in particular spring-loaded.
The optical body 1 can already be secured in the above-described way against a lateral displacement, i.e. to the left/right or upwardly/downwardly, or the main body 101 is formed accordingly, such that a displacement of this type is prevented. By way of example, a displacement of this type can be prevented by the receptacles described below and/or by walls delimiting the stops 121, 122 on all sides.
As can be inferred from
Adjacently arranged receptacles 111, 112; 112, 113; 113, 114; 114, 115 are separated here in the specific example in each case by a common separation web 212, 223, 234, 245, which webs form the delimiting walls 111′, 112′, 113′, 114′, 115′ for the adjacently arranged receptacles 111-115.
The delimiting walls are formed from a light-impermeable material (usually the entire main body is formed from a single light-impermeable material, often in one piece), and therefore the boundary edges 111a′, 112a′, 113a′, 114a′, 115a′ are imaged in a light distribution produced by means of the optical body 1 as vertically extending light-dark edges between the partial light distributions produced by the individual ancillary optics 11-15.
The ancillary optics 11-15 preferably bear directly, i.e. with no distance, against the delimiting walls 111′, 112′, 113′, 114′, 115′ of their receptacle 111-115 so as to obtain an optimal optical display of the light segments.
Delimiting walls 111′, 112′, 113′, 114′, 115′ and therefore boundary edges 111a′, 112a′, 113a′, 114a′, 115a′ are provided here at least between the adjacently arranged receptacles, however it is preferable if the two outer receptacles 111, 115 are each also delimited on their outer side by delimiting walls 111′, 115′.
As can be inferred from
The boundary edges 111a′, 112a′, 113a′, 114a′, 115a′ likewise lie in a common plane E1. In the case of an optics body 1′ according to the prior art, as illustrated in
In accordance with the invention the ancillary optics 11-15 are now arranged and/or configured in such a way that the light-decoupling faces 11b-15b of the ancillary optics 11-15 protrude in the light exit direction beyond the boundary edges 111a′, 112a′, 113a′, 114a′, 115a′ of the boundary walls 111′, 112′, 113′, 114′, 115′, as can be clearly seen in
The focal point F1 (or the focal line) of the projection lens 501 still lies, however, in the plane E1 of the boundary edges, and therefore these boundary edges are sharply imaged in the light pattern, and the light segments are therefore sharply delimited.
Due to the protruding arrangement of the light-decoupling faces with respect to the boundary edges, the boundary edges, which are still arranged in a plane containing the focal point of the downstream projection lens, are still imaged sharply, whereas the light-decoupling faces are imaged in a defocussed manner and accordingly are imaged in a blurred manner. For the light distribution within the individual light segments, this blurred imaging is irrelevant, since a homogeneous light distribution is what matters here, whereas the delimitation of the light segments is still imaged sharply. Due to the defocussing of the light-decoupling faces, however, any dust deposits are also imaged in a defocussed manner and accordingly can no longer be identified and no longer disturb the homogeneity of the light distribution.
The two planes E1, E2 are preferably parallel to one another, as shown.
Number | Date | Country | Kind |
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A 50703/2013 | Oct 2013 | AT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AT2014/050259 | 10/27/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/061822 | 5/7/2015 | WO | A |
Number | Name | Date | Kind |
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20080013333 | Koizumi | Jan 2008 | A1 |
20140204602 | Jungwirth | Jul 2014 | A1 |
20150085523 | Gurtl | Mar 2015 | A1 |
20150124469 | Krenn | May 2015 | A1 |
Number | Date | Country | |
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20160273727 A1 | Sep 2016 | US |