The invention deals with the field of lighting and/or signalling, in particular for motor vehicles. It relates more particularly to a light device comprising a light source, a reflector and an optic for forming rays thus emitted and deflected, arranged in relation to one another for the formation of a light beam in accordance with regulation.
In the context of application to a motor vehicle, it is known practice to associate with a light source a divergent lens to form the forming optic. The arrangement of the object focal point of this lens opposite the light source thus makes it possible to obtain compact light devices, thus offering a greater latitude in the design of the lighting and/or signalling devices.
The use of divergent lens is thus associated with light modules in which an element commonly used elsewhere, namely a shield, or folder, that makes it possible to create a beam with cut off whose edge corresponds to the form of an edge of said shield, is dispensed with. When the lens is associated with existing sources of filament, xenon or LED type, the form and the size are influenced by the source, globally square or rectangular, such that only a beam with flat cut off can be obtained.
In order to produce a beam with cut off, the addition of a specific light module is then necessary for the formation of the inclined part of the cut off. This cut off is obtained by alignment of the top edge of the images of the source in the projected beam. This alignment associated with the size of the sources leads to a thick beam with the light concentrated in front of the vehicle which risks dazzling the driver.
The present invention lies within this context of the search for a light device that is particularly compact and that can generate a beam with cut off. It aims to propose a light device of simple design, limiting the number of components inside the device. In this context, the invention proposes a light device, in particular a lighting and/or signalling device for a motor vehicle, comprising a light source driven to produce the emission of light rays, and a collecting optic, arranged facing the light source to deflect the emitted light rays, and a ray-forming optic for emitting a light beam out of the device.
According to the invention, these various components are particular in that:
Moreover, a collecting optic should be understood in particular to be a reflector or a lens, the reflector offering the advantage of being able to reduce the axial bulk.
In particular, the collecting optic can consist of a reflector of elliptical or pseudo-elliptical form, whose inner face forms a reflection face for the emitted light rays which is turned towards the first face of the substrate of the light source.
According to different features of the invention, taken alone or in combination, it will be possible to provide for:
The light device as has just been described can in particular be implemented for the lighting of a motor vehicle by a beam likely to take the form of a beam with cut off, the collecting optic and the divergent lens being configured so as to form the beam, with cut off or not after refraction by the lens of the rays emitted by the source and deflected by the collecting optic. The light device can thus project a lighting and/or signalling beam such as a lowbeam, a fog beam, and/or a front bending light.
In the latter case in particular, the cut off edge of the beam with cut off can be generated by light rays emitted from an edge of the light source with light-emitting elements; and this cut off edge of the beam with cut off can be generated by light rays emitted from an edge of the light source with light-emitting elements which is configured to emit rays of strong luminance. As previously, strong luminance should be understood to mean rays whose luminance is stronger than the luminance of the rays of a neighbouring zone.
The features of the invention mentioned above, and others, will become more clearly apparent on reading the detailed description below of nonlimiting examples, referring to the attached drawings in which:
and
A light device 1, in particular for the lighting and/or signalling of a motor vehicle, comprises a light source 2, in particular housed in a housing closed by an outer lens and which defines an internal reception volume 3, schematically represented in
In
The forming optic 6 is centred on an optical axis 60 of the light device according to the invention, on which the light source is also arranged. In the example illustrated, the light source 2 is centred transversely on the optical axis 60 (as can be seen in
The light source 2 is oriented such that the rays that it emits are directed mainly towards the ray deflection element 4, a shield here not represented being able to be arranged in the vicinity of the light source to block rays which would go towards the forming optic without first entering into contact with the deflection element. Such a shield would in practice be substantially vertical and arranged in proximity to the source, between the source and the forming optic.
The light source 2 comprises, according to the invention, a plurality of light-emitting elements 8, of submillimetric dimensions, which are arranged protruding from a substrate 10 so as to form, here, rods of hexagonal section. The light-emitting elements extend at right angles to the substrate and at right angles to the optical axis of the device, towards the ray deflection element 4. Provision can in particular be made for, in this context, the optical axis to be situated at mid-height of the mean height of the light-emitting elements with which this light source 2 is equipped.
As a variant, it is also possible to place the source under the axis which would then run in the vicinity of the top emitting surface formed in the vicinity of the free end of the light-emitting elements, if necessary in the vicinity of a top surface of a wavelength conversion material.
These light-emitting elements 8 can be grouped together, in particular by electrical connections specific to each set, in a plurality of zones. In the case illustrated in
As specified, the frame 7 acts as a support element of the light source 2 and that of a cooling device associated with the light source, the light source with light-emitting elements here being glued onto this cooling device. As a variant, the light source can be soldered onto a printed circuit board, itself assembled with the frame forming a heat sink, possibly by an adhesive that is a good conductor of heat.
The ray deflection element 4, in the example illustrated, takes the form of an elliptical reflector, or at the very least one that is configured elliptically, that is to say having two optical focal points such that the rays passing through the first focal point before their deflection by the reflector pass through the second focal point after their deflection. It is understood that first focal point F1 should be understood, if necessary, to mean a plurality of first focal points, and in an optimized solution, a row of first focal points corresponding to an edge of the source, and that second focal point F2 should be understood, if necessary, to mean a curved flat line as represented in
The forming optic 6 takes the form of a divergent lens, as schematically illustrated in
Firstly, the structure of a semiconductor light source 2 comprising light-emitting elements of submillimetric dimensions, in the form of rods, will be described, in particular by referring to
The light source 1 comprises a plurality of light-emitting rods 8 which originate from a first face of a substrate 10. Each light-emitting rod, here formed by the use of gallium nitride (GaN), extends at right angles, or substantially at right angles, protruding from the substrate, here produced based on silicon, other materials like silicon carbide being able to be used without departing from the context of the invention. As an example, the light-emitting rods could be produced from an alloy of aluminium nitride and gallium nitride (AlGaN), or from an alloy of phosphides of aluminium, of indium and of gallium (AlInGaP).
The substrate 10 has a bottom face 12, onto which is added a first electrode 14, and a top face 16, protruding from which extend the light-emitting rods 8, serving as the first face of the substrate described previously, and onto which is added a second electrode 18. Different layers of materials are superposed on the top face 16, in particular after the growth of the light-emitting rods from the substrate, which is here obtained by an ascending approach. Among these various layers, there can be at least one layer of electrically conductive material, in order to allow the electrical power supply of the rods. This layer is etched in such a way as to link particular rods to one another, the switching on of these light-emitting rods then being able to be controlled simultaneously by a control module, not represented here. It will be possible to provide for at least two light-emitting rods, or at least two groups of light-emitting rods, to be arranged to be switched on separately via a system controlling the switching-on.
As specified previously, the intent is to connect the light-emitting rods in sets of rods that are selectively addressable in relation to one another and within which each rod is driven simultaneously, these sets here taking the form of strips, three of them in the example illustrated in
The light-emitting rods are stretched from the substrate and, as can be seen in
Each light-emitting rod extends according to an axis of elongation 22 defining its height, the base of which rod being arranged in a plane 24 of the top face 16 of the substrate 10.
The light-emitting rods 8 of a same light source advantageously take the same form. They are each delimited by a terminal face 26 and by a circumferential wall 28 which extends along the axis of elongation of the rod. When the light-emitting rods are doped and are the object of a polarization, the resulting light at the output of the semiconductor source is emitted essentially from the circumferential wall 28, it being understood that light rays can also exit from the terminal face 26. The result thereof is that each light-emitting rod acts as a single light-emitting diode, and that the luminance of this source is enhanced on the one hand by the density of the light-emitting rods 8 present and on the other hand by the size of the lighting surface defined by the circumferential wall and which extends therefore over all the perimeter, and all the height, of the rod.
The circumferential wall 28 of a light-emitting rod 8, corresponding to the shell of gallium nitride, is covered by a layer of transparent conductive oxide (TCO) 29 which forms the anode of each rod complementing the cathode formed by the substrate. This circumferential wall 28 extends along the axis of elongation 22 from the substrate 10 to the terminal face 26, the distance from the terminal face 26 to the top face 16 of the substrate, from which the light-emitting rods 8 originate, defining the height of each rod. As an example, provision is made for the height of a light-emitting rod 8 to lie between 1 and 10 micrometres, whereas provision is made for the greatest transverse dimension of the terminal face, at right angles to the axis of elongation 22 of the rod concerned, to be less than 2 micrometres. It will also be possible to provide for defining the surface of a rod, in a sectional plane at right angles to this axis of elongation 22, within a range of determined values, and in particular between 1.96 and 4 micrometres squared.
It is understood that, in the formation of the light-emitting rods 8, the height can be modified from one zone of the light source to the other, so as to increase the luminance of the corresponding zone when the mean height of the rods of which it is composed is increased. Thus, one group of light-emitting rods can have a height, or heights, differing from another group of light-emitting rods, these two groups being constituents of the same semiconductor light source comprising light-emitting rods of submillimetric dimensions.
It can be seen in particular in
The form of the light-emitting rods 8 can also vary from one device to another, in particular on the section of the rods and on the form of the terminal face 26. The rods have a generally cylindrical form, and they can in particular, as illustrated in
Moreover, the terminal face 26 can have a form that is substantially flat and at right angles to the circumferential wall, such that it extends substantially parallel to the top face 16 of the substrate 10, as is illustrated in
In a variant not represented, the semiconductor light source 2 can further comprise a layer of a polymer material in which the light-emitting rods are at least partially embedded. The polymer material, which can in particular be based on silicone, creates a protective layer which makes it possible to protect the light-emitting rods without hampering the diffusion of the light rays. Furthermore, it is possible to incorporate, in this layer of polymer material, wavelength conversion means, and for example luminophores, capable of absorbing at least a part of the rays emitted by one of the rods and of converting at least a part of said absorbed excitation light into an emission light having a wavelength different from that of the excitation light. It will be equally possible to provide for the wavelength conversion means to be embedded in the mass of the polymer material, or else for them to be arranged on the surface of the layer of this polymer material.
The light source can further comprise a coating of material reflecting the light which coating is arranged between the light-emitting rods 8 to deflect the rays, initially oriented towards the substrate, towards the terminal face 26 of the light-emitting rods 8. In other words, the top face 16 of the substrate 10 can comprise a reflecting means which returns the light rays, initially oriented towards the top face 16, towards the output face of the light source. Rays which otherwise would be lost are thus recovered. This coating is arranged between the light-emitting rods 8 on the layer of transparent conductive oxide 29.
The light-emitting rods 8 are arranged in a two-dimensional matrix. This arrangement could be such that the rods are arranged staggered. Generally, the rods are arranged at regular intervals on the substrate 10 and the distance separating two immediately adjacent light-emitting rods, in each of the dimensions of the matrix, must be at least equal to 2 micrometres, in order for the light emitted by the circumferential wall 28 of each rod 8 to be able to exit from the matrix of light-emitting rods. Moreover, provision is made for these separation distances, measured between two axes of elongation 22 of adjacent rods, not to be greater than 100 micrometres.
The light-emitting rods of submillimetric dimensions define, in a plane, substantially parallel to the substrate, a determined emission surface, which has a substantially rectangular form with a determined length and width. As illustrated in
As has previously been described, in the example illustrated according to the invention, the light source 2 has light-emitting rods arranged in three selectively activatable sets which each take the form of a strip, these strips being stacked along the optical axis 60. These strips respectively forming the first set 81, the second set 82 and the third set 83 are separated from their immediate neighbour by a demarcation line, as is notably visible in
In each of the cases, it is understood that the rods, associated respectively with one or other of the two sets on either side of the demarcation line, are connected electrically for the sets to be selectively activatable.
The first set 81 has rods whose mean height is greater than the mean height of the rods of the second set 82 and greater than that of the rods of the third set 83. As specified previously, the light source 1 is arranged such that it is the first set 81 which is arranged on the first focal point of the ray deflection element 4. The sets of rods arranged further away from this first focal point have a mean rod height substantially equal to one another, but less than that of the first set 81, which thus generates a greater luminance than the other sets of rods. The result thereof is a light source which exhibits a variable luminance along the direction of the optical axis.
In this context, provision can be made to configure each of the light-emitting elements such that the first set 81 of rods exhibits a luminance 3 to 4 times greater than the mean luminance of the other sets of rods.
It is understood from the above that driving elements associated with the light source 2 are configured to drive the activation of the first set 81 separately from that of the second set 82 and/or the third set 83.
There now follows a more detailed description of the positions relative to one another of the light source 2, of the elliptical reflector forming the optical deflection element 4 and of the divergent lens forming the forming optic 6, and the impact that that has on the path of the rays.
The elliptical reflector has a first focal point on which is positioned the light source, and more particularly the longitudinal end edge corresponding to the first set of rods, and a second focal point coinciding with the object focal point of the divergent lens. This matching point of the second focal point of the reflector and of the focal point of the divergent lens is situated on the other side of the divergent lens in relation to the light source and the reflector. In other words, the divergent lens is positioned between the first and the second focal points of the reflector.
First rays (represented in
Second rays (represented in
In other words, the reflector is adapted to project the image of the very bright part of the source opposite the divergent lens, in the vicinity of the object focal point of this divergent lens, such that the corresponding rays emerge parallel to the optical axis by forming the cut off of the beam emitted at the output of the divergent lens.
It is thus possible to produce a beam of low beam type, with a quite sharp beam cut off delimited by the edge of the light source arranged on the first focal point of the elliptical reflector.
It is consequently worth noting the benefit of having a first set 81 of rods, arranged in contact with this edge of the light source corresponding to the cut off edge, which is configured to have a higher luminance than the other sets of rods. A zone of strong light intensity is thus produced in the beam projected, just under the cut off edge.
In the example illustrated, the stronger luminance is obtained by a greater mean height of the rods 8 of this first set 81, but it will be understood that this strong luminance could be obtained differently, by a greater density of rods for example. In each of these cases, a zone of strong luminance is arranged on the rear longitudinal end edge 80 of the light source 2, that is to say the edge of the light source opposite the divergent lens. As was able to be specified previously, this edge exhibiting a zone of strong luminance is arranged on the first focal point of the elliptical or pseudo-elliptical reflector. This is made visible in particular in
In a basic mode of operation, driving elements associated with the light source control the selective activation of the light-emitting rods present in each of the sets of rods. The driving of these sets can be selective in that the power supply intensity of each of the sets of rods varies according to their distance from the longitudinal end edge 80 of the light source 2. A beam of low beam type is produced here, with a cut off edge, it being understood that other types of beam could be produced, in particular by modifying the position of the light source in relation to the first focal point of the reflector. It is understood that, to modify the luminance from one zone to another, it will be possible to act on the distinct power supply of the zones and equally on the height and/or the density of the light-emitting elements protruding from the substrate, and that it will be possible to implement one and/or other of these embodiments described previously.
The present invention applies quite particularly to a front headlight of a motor vehicle, and it is incorporated in particular in a vehicle front face.
The described embodiments apply to light sources with electroluminescent rods protruding and extending from the same substrate as described above but also to light sources with electroluminescent blocks obtained by cutting superimposed electroluminescent layers on the same substrate, the blocks replacing the rods.
Obviously, various modifications can be made by the person skilled in the art to the structure of the light device which has just been described by way of nonlimiting example, provided that it uses at least one semiconductor light source with light-emitting elements, a collecting optic, and, for example, an elliptical or pseudo-elliptical reflector, and a divergent lens. In any case, the invention cannot be limited to the embodiment specifically described in this document, and extends in particular to any equivalent means and to any technically operable combination of these means.
Number | Date | Country | Kind |
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17 52041 | Mar 2017 | FR | national |
Number | Name | Date | Kind |
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5897196 | Soskind | Apr 1999 | A |
20090027909 | Albou | Jan 2009 | A1 |
20170059110 | Reiss et al. | Mar 2017 | A1 |
Number | Date | Country |
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0 798 506 | Oct 1997 | EP |
3 127 747 | Feb 2017 | EP |
WO 2017025445 | Feb 2017 | WO |
Entry |
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French Preliminary Search Report dated Sep. 1, 2017 in French Application 17 52041 filed on Mar. 13, 2017 (with English Translation of Categories of Cited Documents). |
Number | Date | Country | |
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20180266640 A1 | Sep 2018 | US |