Patent Grant
11248765
The invention relates to an optical device for a motor vehicle headlight, wherein the device comprises:
The invention further relates to a motor vehicle headlight with at least one lighting device in accordance with the invention, or with at least one light module with at least one lighting device in accordance with the invention.
The above-cited lighting devices are usually used in connection with light modules or motor vehicle headlights so as to generate light distributions, preferably a dipped beam and/or a full beam distribution. For this purpose, light from light sources is fed into the respective light-receiving surfaces of the optical waveguide bodies, which light is propagated in the optical waveguide bodies by means of reflection and/or total reflection on the side walls of the optical waveguide bodies, wherein the light exits again via the light-emitting surfaces of the respective optical waveguides.
For this purpose it is necessary that the primary optical element, that is to say, the optical waveguide bodies of the primary optical element, are precisely positioned with reference to the corresponding light sources.
For this purpose, for example, a holder can be provided, which holds the optical waveguide bodies in position with reference to the light sources, wherein such a holder can be made of a plastic. During operation of the lighting device, that is to say, the light sources, high temperatures can occur as a result of the heat radiation from the light sources. Since the optical waveguide bodies, and thus also the holder, are positioned relatively close to, and at a small distance from, the light sources, undesired thermal damage or deformation of the holder can occur, and thus also an alteration in the position of the optical waveguide bodies, or thermal damage can also occur as a result of the exposure to heat of the light sources in operation, by virtue of heat conduction.
In turn, damage to, or misalignment of, the optical waveguide bodies can result in the light image as depicted not meeting the desired requirements.
For this reason, a covering element is arranged between the holder and the light sources, which serves as a kind of heat shield. At the same time, however, it is important to ensure that the distance between the optical waveguide bodies and the light sources is unaltered, and that a suitable mounting is found for fixing on the holder, since there is little installation space between the holder and the light sources.
It is an object of the invention to provide an improved optical device for a motor vehicle headlight.
This object is achieved in that the at least one second engaging element is designed as a projection projecting from the holder, with an engaging section, which has a height and a width extending away from the holder, and an end section, which has a height and a width, and wherein the at least one first engaging element is designed as a guide recess in the covering element, wherein the guide recess has a first region and a second region, which in comparison to the first region is tapered, which second region extends along a slip-on direction and has a width extending transversely to the slip-on direction, wherein the projection can be inserted into the first region of the guide recess and can be moved within the guide recess in such a manner that the second region of the guide recess can be slid onto the engaging section of the projection by means of a movement of the covering element in the slip-on direction.
The primary optical element can advantageously be made in one piece from a transparent, light-conducting, and mouldable, plastic.
“In one piece” is understood to mean that the primary optical element is manufactured in one piece, preferably by means of an injection moulding process.
In an appropriate form of embodiment, the primary optical element can be made of a silicone material.
By virtue of the elastomeric properties of a silicone material, removal from the mould during the production of the primary optical element is possible without an additional slider, as the primary optical element is preferably produced by means of an injection moulding process.
Likewise, it can be advantageous for the primary optic to be made of a poly(organo)siloxane.
Provision can advantageously be made for the holder to have an opening region with at least one opening, in which the optical waveguide bodies can be received and positioned.
The individual optical waveguide bodies can be held in their position with reference to the light sources particularly well, if the holder and/or the covering element has an opening for each optical waveguide body in which the associated optical waveguide body is received and positioned with a precise fit.
The openings take the form of holes or receptacles in the holder or the covering element, with a precisely matched cross-section for the respective optical waveguide body; these are inserted into the associated openings, and held in the desired position by the holder.
Provision can be made for the holder and/or the covering element to have openings corresponding to the number of optical waveguide bodies, each of which is assigned to one optical waveguide body.
It can be beneficial if the holder and/or the covering element receive the optical waveguide bodies in their end regions facing towards the light-receiving surfaces.
Here the optical waveguide bodies can protrude slightly rearwards from the receptacles, that is to say, the openings of the covering element, or can finish flush with the latter.
Provision can, for example, be made for the optical waveguide bodies to be designed in the shape of a truncated cone or a trapezoid.
In principle, all multi-sided pyramid bases come into consideration, e.g. hexagonal bases, for instance in the form of wedge-shaped honeycombs. The base surface shape is closely related to the LED chip arrangements and the desired light shaping, wherein the light entrance and exit can be significant.
Furthermore, if the covering element is designed as a plate, or from sheet metal, provision can be made for this plate to rest on the holder in a slipped-on state. Here provision can be made for the plate or sheet to have deformations corresponding to the shape of the holder.
Advantageously, the width of the engaging section can be less than the width of the end section.
This ensures that the covering element is held positively in a form fit on the holder in a slipped-on state.
Provision can furthermore be made for the width of the second region of the guide recess to be at least equal to the width of the engaging section of the projection.
The width of the engaging section should preferably be only slightly less than the width of the second region of the guide recess, so as to prevent the covering element from moving transversely to the slip-on direction.
Likewise, it can be beneficial if the end section of the projection has a taper with respect to its height in the opposite direction to the slip-on direction.
This makes it easier to put on, and then slip on, the covering element, that is to say, the individual engaging sections of the projections.
Provision can advantageously be made for the covering element to have a thickness, wherein the height of the engaging section of the projection corresponds at least to the thickness of the covering element, preferably to the thickness in the region of the guide recess of the covering element.
The covering element can advantageously have a constant thickness.
In an appropriate form of embodiment, the holder can have at least one stop element, which stop element is set up so as to limit the movement of the covering element in the direction of the slip-on direction, wherein at least two stop elements are preferably provided.
Provision can furthermore be made for at least two first engaging elements, and at least two second engaging elements corresponding to the first engaging elements, to be provided.
At least one first engaging element and a corresponding second engaging element are preferably arranged above and below the openings of the covering element, that is to say, above and below the opening region of the holder.
The terms “above” and “below” refer to the longitudinal axis of the primary optical element, that is to say, of the main body of the primary optical element, preferably transverse to the main direction of radiation of the light sources, in the assembled state of the optical device.
“Main direction of radiation” is understood to mean the direction in which the light sources emit the most, that is to say, the strongest light, as a result of their directionality.
It can be beneficial if at least one thickening element is arranged on a side of the end section of the projection opposite the covering element in the slipped-on state of the covering element, that is to say, on a side of the end section of the projection facing towards the holder, wherein the distance between the holder and the at least one thickening element is less than the height of the engaging section of the projection, wherein at least two thickening elements are preferably arranged on the end section.
By this means the covering element, when it is slipped onto the holder, is additionally pressed onto the holder, so that the covering element is fixed as firmly as possible onto the holder.
The thickening elements can preferably be rounded, that is to say, form part of a spherical body. By this means it is even easier to slip on the covering element.
Provision can be made for at least one latching lug to be arranged on the holder, which is set up so as to latch in a fixing recess corresponding to the latching lug, which recess is provided on the covering element.
The latching lug and the fixing recess are preferably arranged in such a way that the latching lug only fully engages in the fixing recess when the covering element rests against, or abuts against, the stop elements.
This ensures that the covering element is also fixed in the opposite direction to the slip-on direction.
The object is also achieved with an illumination device with at least one optical device and a number of light-emitting light sources corresponding to the number of optical waveguide bodies, which light is provided for feeding into the at least one optical device.
The illumination device preferably takes the form of a “pixel light device”, wherein the light sources are arranged in rows and columns.
In such a “pixel light device”, the light sources can be controlled independently of each other, as a result of which different light distributions can be generated, in particular an adaptive full beam light distribution.
It can be beneficial if the light sources in each case comprise one or more light-emitting diodes.
Preferably, provision can be made for each light source to comprise in each case one or a plurality of light-emitting diodes. Each light source can preferably be controlled separately, and can be switched on and off accordingly, and can preferably also be dimmed. If a light source consists of a plurality of light-emitting diodes, it can also be advantageous if each of the light-emitting diodes can be controlled separately.
Here provision can be made for exactly one, or at least one, light source to be assigned to each optical waveguide body.
The object is also achieved by a light module with at least one lighting device in accordance with the invention.
Furthermore, the object is achieved with a motor vehicle headlight with at least one lighting device in accordance with the invention, or a light module with at least one lighting device in accordance with the invention.
With a lighting device and/or light module in accordance with the invention, for example, a dipped beam and/or a full beam can be generated, for which purpose, for example, the left headlight and the right headlight each comprise a lighting device and/or light module in accordance with the invention, with which the left-hand and the right-hand parts of the light distribution are generated respectively. In the direction of light emission in front of the holder, a secondary optical element, usually a lens, is provided, by means of which the respective light distribution can be generated.
However, the lighting device and/or light module in accordance with the invention can also be used for a reversing light.
In what follows the invention is explained in more detail with the aid of exemplary drawings. Here:
The optical device 1 comprises a primary optical element 100 with a main body 101 and with a plurality of optical waveguide bodies 110 projecting from the main body 101, which optical waveguide bodies in
The device 1 furthermore comprises a holder 200, on which the main body 101 of the primary optical element 100 is arranged, that is to say, can be attached, on a front side of the holder 200, wherein the optical waveguide bodies 110 of the primary optical element penetrate the holder 200 through an opening region 210 of the holder 200.
The device 1 furthermore comprises a covering element 300, which is arranged on a rear face of the holder 200, facing away from the main body 101 of the primary optical element 100, and has a thickness d1, preferably a constant thickness, wherein the covering element 300 has a number of openings 310 corresponding to the number of optical waveguide bodies 110, and openings 310 corresponding to the optical waveguide bodies 110, which openings 310 are set up so as to receive the optical waveguide bodies 110 of the primary optical element 100, and to hold them in position.
In the example shown, the covering element 300 can be connected to the holder 200 by means of five first engaging elements 410 arranged on the covering element 300, which in each case are provided so as to engage with second engaging elements 420 arranged on the holder 200.
In the example of embodiment shown in the figures, the second engaging elements 420 are in each case designed as a projection 420 projecting from the holder 200, and the first engaging elements 410 are in each case designed as a guide recess 410 in the covering element 300.
The projections 420 also have, as can be seen more clearly in
Each guide recess 410 has a first region 411 with a width b4 and a length 14, and a second region 412 that is tapered in comparison to the first region 411, which second region 412 extends along a slip-on direction X, and has a width b3 extending transversely to the slip-on direction X, as can be seen in
A projection 420, that is to say, its end section 422 can in each case be passed through the first region 411 of a guide recess 410, so that the second region 412 of the guide recess 410 can be pushed onto the engaging section 421 of the projection 420 by means of a movement of the covering element 300 in the slip-on direction X, wherein the width b3 of the second region 412 of the guide recess 410 corresponds at least to the width b1 of the engaging section 421 of the projection 420, and wherein the height h1 of the engaging section 421 of the projection 420 corresponds at least to the thickness d1 of the covering element 300, preferably to the thickness in the region of the guide recess 410 of the covering element 300.
Furthermore, the width b2 and the length 12 of the end section 422 of the projection 420 are respectively at least slightly less than the width b4 and the length 14 of the first region 411 of the guide recess 410.
To this end
Furthermore, it can be seen in
For this purpose, the holder 200 in the example shown has two stop elements 210, which stop elements 210 are set up so as to limit the movement of the covering element 300 in the direction of the slip-on direction X. The stop elements 210 are arranged on the holder 200, for example, in such a way that an outer edge region, that is to say, an end edge of the covering element 300, rests or abuts against the stop elements 210 in a fully slipped-on state of the covering element 300.
Furthermore, a latching lug 220 is arranged on the holder 200, which is set up so as to latch into a fixing recess 320 corresponding to the latching lug 220, which recess is provided on the covering element 300.
| Number | Date | Country | Kind |
|---|---|---|---|
| 18187242 | Aug 2018 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2019/068786 | 7/12/2019 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2020/025291 | 2/6/2020 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 9664847 | Krenn | May 2017 | B2 |
| 20050140270 | Henson et al. | Jun 2005 | A1 |
| 20140226355 | Blandin et al. | Aug 2014 | A1 |
| 20150204499 | Pawliczek et al. | Jul 2015 | A1 |
| 20170151901 | Sazuka | Jun 2017 | A1 |
| 20170370550 | Japs et al. | Dec 2017 | A1 |
| 20180264994 | Stoehr | Sep 2018 | A1 |
| Number | Date | Country |
|---|---|---|
| 102012213843 | Sep 2013 | DE |
| 102017209815 | Dec 2018 | DE |
| 3339720 | Dec 2020 | EP |
| Entry |
|---|
| International Search Report for PCT/EP2019/068786, dated Oct. 18, 2019. (2 pages). |
| European Search Report for EP Application No. 18187242, dated Jan. 16, 2019. (1 page). |
| Number | Date | Country | |
|---|---|---|---|
| 20210310627 A1 | Oct 2021 | US |
