FR2979971A1 - Signaling and/or lighting device for use in headlight of car to produce code beam, has optical modules, where each module has first assembly or second assembly or complex surface reflector that produces, towards front, light beam with cut - Google Patents

Abstract

The device (21) has optical modules (22, 22 ', 23, 23') mounted on different supports (27, 28). Each module has a first assembly or a second assembly or a reflector whose complex surface collects light from a light source (51) and produces, towards front, a corresponding light beam with a cut. Each assembly has a collector (53) to collect the light, and a bending unit (54) with a cut edge to authorize only the passage of a part of the light from the collector for producing the corresponding light beam and its cut. The second assembly has a lens to focus the light from the collector. The light source is a single chip LED.

Description

The present invention relates to a lighting and / or signaling device. Although not exclusively, such a lighting and / or signaling device may be in the form of a motor vehicle light projector, for the purpose of producing for example a coded beam. For such an application, it will be understood that it is essential that the projection on the road of the light beam generated by the lighting and / or signaling device does not exceed a predetermined limit, in order to avoid dazzling a arriving motorist. in front.

A lighting and / or signaling device arranged to produce a light beam having a cutoff, namely the transition between a zone illuminated by the beam and a zone not illuminated by said beam, is already known, these zones being arranged on the one hand. and other of the cut.

When it comes to producing a V-cut beam, that is to say whose cut has two branches forming between them a non-zero angle, it can be used a lighting and signaling device according to that described in document FR 2 844 033. This device described in the aforementioned document has an optical axis and comprises: a first optical module capable of generating a first light beam having a projection on a screen perpendicular to the axis optical, a plane cut; and a second optical module capable of generating a second light beam having, in projection on a screen perpendicular to the optical axis, a cutoff comprising two branches forming between them a non-zero angle.

Moreover, in this device, the optical modules, each formed of at least one light source, are arranged relative to one another so that, in projection on a screen perpendicular to said optical axis, the light beams that they generate are at least partially superimposed.

However, in this document, the optical modules are formed by different optical elements and therefore have different structures, which generates a lack of standardization and, therefore, significant costs of design and manufacture of these different optical elements. These structural differences between these optical elements thus hinder the standardization of some of these components, preventing the cost of these components from being reduced. Moreover, the structure proposed in the aforementioned prior document raises problems of industrialization, as well as of compatibility with the constraints of the automotive sector, in particular the economic constraints inherent in this sector. The object of the present invention is therefore to limit the manufacturing costs of such a lighting and / or signaling device.

The subject of the invention is therefore a lighting and / or signaling device, in particular a motor vehicle, which has an optical axis and which comprises: a first optical module capable of generating a first light beam having, in projection on a screen perpendicular to the optical axis, a plane cut, in other words rectilinear; and a second optical module capable of generating a second light beam having, in projection on a screen perpendicular to the optical axis, a cutoff comprising two branches forming between them a non-zero angle, hereinafter referred to as a V-cut, said optical modules being arranged relative to each other so that, in projection on a screen perpendicular to said optical axis, said light beams are at least partially superimposed to form a resulting light beam, characterized in that said optical modules comprise each: - the assembly: ^ a collector arranged to collect the light from a light source, ^ a folder with a cutting edge to let only a portion of the beam from the collector and thereby producing a corresponding light beam and cut-off, optionally comprising a surface of said reflecting light, and an arranged reflector for corresponding luminous means, or the assembly: producing forwards said beam of a collector arranged to collect the light coming from a light source, of a folder having at least one cutting edge in view of allowing the passage of only a portion of the beam from the collector and producing the corresponding light beam and its cut, such a folder may also for example include a reflective surface, and a lens arranged to focus the light beam from the collector. or a mirror, or reflector, having a complex surface configured to collect light from a light source and produce the light beam having a cutoff forward.

Thus, thanks to the invention, the optical modules can be formed by identical optical elements, able to generate indifferently the first plane cut-off beam and the second V-cut beam. It follows that these optical modules, structures similar, can be manufactured standard, in series and taking advantage of common manufacturing tools, which significantly reduces design and manufacturing costs. Preferably, the optical modules are arranged relative to each other so that, in projection on a screen perpendicular to the optical axis, the cut of the first light beam and one of the branches of the V cut the second light beam are parallel to a horizontal axis of said screen. In this case, the optical modules can be arranged relative to each other so that, in projection on a screen perpendicular to the optical axis, the branch of the V cut of the second light beam parallel to the horizontal axis of said screen is located above the cutoff of the first light beam. The mounting of the first optical module with respect to the second optical module guarantees this relative positioning of the beams, which avoids any need to adjust one beam relative to the other. Indeed, the current lighting standard for the beam code, and the settings that they imply, need only be respected by one of the beams, the first light beam being voluntarily fixed so as to project its cut just below the V cut of the second light beam. Thus, the first beam greatly improves the lighting without requiring adjustment in accordance with the aforementioned standard.

In the case where the cutoff of the first light beam is blurred, the optical modules can be arranged relative to each other so that, in projection on a screen perpendicular to the optical axis, the fuzzy cut of the first beam light is included in the second light beam.

In addition, the optical modules can be arranged relative to each other so that, in projection on a screen perpendicular to the optical axis, the cutoff of the first light beam is located below the branch of the V cut of the second light beam parallel to the horizontal axis at an angle between 0.3 ° and 0.6 °. The non-zero angle formed between the two branches of the V cut of the second light beam may be between 8 ° and 15 °.

In a particular embodiment of the invention, the V cut of the second light beam is clear while the cutoff of the first light beam is blurred.

It should be noted that the determination of the sharpness of a cut is made by its gradient, the cutoff being considered clear as soon as the value of the gradient exceeds 0.4, and fuzzy when this value is less than 0.4. Preferably, each optical module comprises a support which receives the constituent components of the assemblies mentioned above. Such a support is for example planar. In one example, such a support is a printed circuit board.

The support of the first optical module extends in particular in a plane substantially parallel to a plane in which the support of the second optical module extends.

According to an advantageous characteristic of the invention, the support of the modules is each formed by a substrate, rigid or flexible, carrying at least two electrically conductive tracks. Such a support is thus formed by the printed circuit board.

Advantageously, at least one light source of each optical module is placed, for example solidarized, on the substrate, this light source being electrically connected to the conductive tracks.

According to an improvement of the invention, the substrate carries a plurality of electronic components, at least some of which are dedicated to the ignition and / or extinguishing of the light source. Advantageously, such a substrate is an isolated metal substrate.

In addition, at least one optical module may comprise at least one light source in the form of a single-chip light emitting diode. The figures of the appended drawing will make it clear how the invention can be realized. In these figures, identical references designate similar technical elements. Figure 1 is a schematic view of a projection on a screen perpendicular to an optical axis of a light beam resulting from the combination of the first superimposed light beam with the second light beam. FIG. 2 is a schematic perspective view of a first embodiment of a lighting and / or signaling device with four optical modules.

FIG. 3 is a diagram showing the projection, on a screen perpendicular to the optical axis, of the plane cutoff light beam generated by at least a first optical module of the device of FIG. 2.

FIG. 4 is a diagram showing the projection, on a screen perpendicular to the optical axis, of the resulting light beam generated by all the optical modules of the device of FIG. 2. FIG. 5 is a perspective view of a lighting and / or signaling device with four identical optical modules, according to a second embodiment of the present invention. FIG. 6 is a perspective view of part of the device of FIG. 5.

Figure 7 is a perspective view of a lighting and / or signaling device with four optical modules, according to a third embodiment of the present invention. FIG. 8 is a perspective view of the respective supports of the optical modules of the device of FIG. 7. FIG. 9 is a perspective view of a lighting and / or signaling device with four optical modules, according to a fourth embodiment embodiment of the present invention.

FIG. 10 is a diagram showing the projection, on a screen perpendicular to the optical axis, of the plane-cut light beam generated by at least one of the first optical modules of the device of FIGS. 5, 7 or 9.

FIG. 11 is a diagram showing the projection, on a screen perpendicular to the optical axis, of the V-shaped sloping cut-light beam generated by at least one of the second optical modules of the device of FIGS. 5, 7 or 9.

FIG. 12 is a diagram showing the projection, on a screen perpendicular to the optical axis, of the resulting light beam generated by at least a first optical module and at least a second optical module of the device of FIGS. 5, 7 and 9.

FIG. 1 shows the projection of the first light beam 4 and the second light beam 6 on a screen perpendicular to an optical axis and placed in front of a lighting and / or signaling device according to the invention. The projection of the first light beam 4 generated by at least a first optical module has a large extent in a horizontal axis X-X '. This first light beam 4 is also located under this horizontal axis X-X '. An upper line of this beam is referenced cutoff 4.1 and it is found that it is flat and parallel to the horizontal axis X-X '.

According to an exemplary embodiment, this planar cut can be sharp, that is to say frank between the illuminated area and the unlit area. Alternatively, this flat cutoff 4.1 can be blurred, the illuminated area gradually decreasing as one enters the unlit area.

FIG. 1 also shows a projection on the same screen of a second light beam 6. This second light beam 6 is generated by a second optical module installed in the lighting and / or signaling device, on a separate but identical support to that of the first optical module. The projection of the second light beam 6 has a smaller extent than that of the first light beam 4, as well as a V-shaped cut. This V-cut, otherwise known as an inclined cut, comprises a first branch 6.1, situated on one side of the optical axis ZZ 'and parallel to the horizontal axis X-X'. This V-cut also comprises a second branch 6.2, on the other side of the optical axis Z-Z ', which rises above the horizontal axis XX' of a non-zero angle α, by example between 8 ° and 15 °. This second beam 6 is parallel on the horizontal axis X-X '. The first light beam 4 and the second light beam 6 are superimposed to form a resulting light beam 50 formed by the combination of the first light beam 4 with the second light beam 6. The function of the first light beam 4 is to provide a wide illumination and diffuse which improves the driver's vision of the road he uses with his motor vehicle. The function of the second beam 6 is to fulfill the conditions required to comply with the standard in force for a code illumination.

The first and second optical modules are also arranged, relative to each other, so that in projection on the screen (XX '; Y-Y') perpendicular to the optical axis Z-Z ', the cut 4.1 of the first light beam 4 and one of the branches 6.1 of the cutting edge of the second light beam are parallel to the horizontal axis XX 'of said screen. More precisely, the cutoff line 4.1 of the first light beam 4 is below the cutoff edge 6.1 of the second light beam 6, a distance referenced 73 separating this cutoff line and this cutoff edge. This distance 73 results from the choice of inclining the first light beam 4 downwards at an angle of between 0.3 ° and 0.6 ° with respect to a plane passing through the light source generating the second light beam 6 and the cutting edge 6.1.

The lighting and / or signaling device thus comprises at least a first optical module and at least a second optical module of identical constitution, which makes it possible to generate the resulting light beam 50 of the code type. Such a device can therefore easily be incorporated in a headlight of a motor vehicle, or possibly formed the headlight of said vehicle. A first embodiment of a lighting and / or signaling device 1, shown in Figure 2, is intended to equip the motor vehicle. This first embodiment illustrates one of the assembly alternatives of the invention, that is to say the complex surface reflective alternative. It has an optical axis ZZ 'and comprises a set of four optical modules 2, 2', 3 and 3 ', of which two first optical modules 2 and 2' are capable of generating the first plane-cut light beam and two second optical modules 3 and 3 'are capable of generating the second "V" cut-off light beam, that is to say forming a non-zero angle, for example equal to a value between 8 ° and 15 °. In this embodiment, these four optical modules 2, 2 ', 3 and 3' are all aligned along the axis X-X ', and all have an optical axis coincident with the axis Z-Z'.

According to this first embodiment, each optical module 2, 2 ', 3 and 3' comprises a light source 51 which takes the form of one or more light-emitting diodes. These light sources 51 are aligned in a rectilinear direction coincident with the axis X-X '.

Each of these modules also comprises a reflector 52 of light with complex surfaces. Such a reflector, otherwise called mirror, forms a single piece by optical module which ensures the return and concentration of light rays on the road, while ensuring the cutoff, for the first light beam, or the V cut, for the second light bleam. At least two first optical modules 2 and 2 'are assembled or joined on the same support 7, called the first support. Similarly, at least two second optical modules 3 and 3 'are assembled or joined on the same support 8, hereinafter called the second support. This first support 7 and second support 8 are distinct but has an identical structure. Similarly, the reflector 52 of each of the first and second modules 2, 2 ', 3 and 3' has an identical structure.

Such a solution makes it possible to standardize the manufacture of the support 7 or 8 and the reflector 52 that can be used in each module. The first support 7 and the second support 8 are for example formed by a rigid or flexible substrate. This substrate can also be metallic, so as to drain calories, while being electrically insulated to drive two opposite potentials of an electric current. It is understood from this that the first support 7 and the second support 8 may be a printed circuit board. Such a substrate provides a mechanical resistance to the assembly formed a plurality of first optical modules 2, 2 'or second optical modules 3, 3'.

The projection of the first light beam 4 generated by the first optical modules 2 and 2 ', on a screen (XX'; Y-Y ') perpendicular to the optical axis ZZ' of the lighting and / or signaling device 1, is shown in Figure 3. This first light beam 4 has a large extent, located under the horizontal axis X-X ', and a cut 4.1 flat and parallel to said horizontal axis X-X'. FIG. 4 shows the projection of the resulting light beam 50 generated by the combination of the first optical module with the second optical module. The first light beam 4 has a large extent under the horizontal axis X-X ', which makes it possible to provide a very wide illumination for the comfort of the driver of the motor vehicle. This resulting light beam 50 also comprises a V-cut generated by the second light beam 6, the first leg 6.1 of which, on one side of the screen (XX '; Y-Y'), is parallel to the horizontal X-X ', and the second branch 6.2, located on the other side of said screen, rises above the horizontal axis XX' of a non-zero angle. A second embodiment of the lighting and / or signaling device 11, according to the present invention, is shown in FIG. 5. This second embodiment illustrates another of the assembly alternatives of the invention. ie collector alternative, folder and lens. This lighting and / or signaling device 11 consists of a juxtaposition of first and second optical modules made according to this particular assembly alternative. This lighting and / or signaling device 11 comprises, in a manner similar to the device 1 described with reference to FIGS. 2 to 4, four optical modules 12, 12 ', 13 and 13' of substantially identical structure, these four modules however being distinct and can be secured to each other by a securing means interposed between each of the modules. Each of the optical modules 12, 12 ', 13 and 13' comprises in this order, in the direction of movement of the light beam: - a collector 53 for collecting light from the light source 51, - a folder 54 having a reflective surface and a cutoff edge for passing only a portion of the beam from the collector 53, and thereby producing the light beam concerned, i.e. the first light beam or the second light beam, and - a lens 55 arranged to focus forward the beam from the collector 53. Note that the lens 55 is mechanically held between an upper arm 56 and a lower arm 57, the latter forming, in another example, a first support 17 or a second support 18 of the components of each optical module listed above. The lighting and / or signaling device 11 also comprises a multiplicity of cooling devices 61 in physical contact with each support 17, 18. More specifically, at least one first optical module 12 or 12 'and at least one second optical module 13 or 13 'comprises a cooling device 61, these being of identical structure and in particular from the same production line.

A function of these cooling devices 61 is to dissipate the calories generated by the light-emitting diodes forming one or more light sources 51. These cooling devices 61 are also intended to dissipate the calories generated by the electronic components which are mounted on each card. circuit board incorporated in each optical module. Finally, these cooling devices 61 provide a third function which consists in reinforcing the mechanical strength of the support 17, 18, that is to say of the electronic card with which each cooling device is in contact. Such an organization makes it possible to limit the mechanical stress experienced by the printed circuit board. It is understood from the structure described above that a high level of standardization is achieved because the components of each of at least one of the first optical modules 12 or 12 ', generator of the plane cut light beam, and at least one of the second optical modules 13 or 13 ', generator of the cut-off beam, come out of the same production line. Figure 6 illustrates the same optical modules as those shown in Figure 5. In contrast, the lens, the upper arm and the collector have been removed to make apparent the internal structure of each module 12, 12 ', 13 and 13'. The printed circuit board 9 of each optical module is here visible and it is found that it carries the light source 51, the latter being in particular at least one light-emitting diode secured to one face of the printed circuit board 9.

This FIG. 6 also shows the cooling device 61 of each optical module 12, 12 ', 13 and 13', which comprises a plane sector 58 on which the printed circuit board 9 lies flat and a dispersion sector 59 comprising a plurality fins 60 which extends in a direction perpendicular to the plane sector 58.

Finally, each optical module includes its own folder 54 dedicated to the creation of a light beam cut flat or inclined, possibly sharp or blurred. A particular embodiment of the lighting and / or signaling device 21, according to the present invention, is shown in FIG. 7. This lighting and / or signaling device for a motor vehicle comprises, in a manner similar to the devices 1 or 11 previously described, four optical modules 22, 22 ', 23 and 23'. The first optical modules 22 and 22 'thus make it possible to generate the first plane-cut light beam, while the second optical modules 23 and 23' make it possible to generate the second V-cut light beam. Moreover, the first optical modules 22 and 22 'are united on the same first support 27 and the second optical modules 23 and 23' are united on the same second support 28, distinct from the first support 27. This first support 27 and the second support 28 are advantageously formed by a card of a printed circuit carrying a pair of light sources 51. The first optical modules 22 and 22 'gathered on the first support 27 are arranged below the second optical modules 23 and 23' assembled on the second support 28. In other words, at the less a first module is disposed higher than a second optical module along a vertical axis. This third embodiment illustrates one of the assembly alternatives of the invention, that is to say the alternative collector, folder and reflector traveled in this order in the direction of movement of the light beam. Thus at least a first optical module 22 or 22 'and at least a second optical module 23, 23' each comprises a collector 53 arranged to collect the light from a light source 51, at least one folder 54 having a cut edge in order to pass only a portion of the light beam from the collector 53 and thereby produce a corresponding light beam and its cut, and a reflector 71 arranged to produce the corresponding light beam towards the front of the vehicle.

Note that the folder optionally comprises a reflecting surface so as to return the light rays that have been stopped by the cutting edge of the folder 54. This Figure 7 shows an improvement of the invention. When the lighting and / or signaling device 21 comprises at least one pair of the same optical module, it is expected that the folder 54 is formed of a single piece for two juxtaposed optical modules 23 and 23 '. This folder 54 is then attached to these two optical modules and connected thereto, in particular, by a plurality of fixing pins 74.

Thus, each of the first and second optical modules consists of a light source 51 advantageously formed by a light-emitting diode, of single-chip or multi-chip type. In front of this light source is disposed the collector 53 which returns the light rays emitted by the light source 51 in the direction of the folder 54. Each of these optical modules finally comprises the reflector 71 whose function is to redirect the light rays having crossed the folder to form the first light beam or the second light beam.

According to a feature of this third embodiment, the two collectors 53, the two folders 54 and the two reflectors 71 of the two second optical modules 22 and 22 'form a single piece. The latter is manufactured from the same molding step. It may also be the same for a pair of first optical modules 23 and 23 '.

The lighting and / or signaling device 21 is mounted on a chassis 75 of a front headlight of a motor vehicle, such a chassis being able to be common to the first optical modules 22, 22 'and to the second optical modules 23, 23 .

FIG. 8 shows that the first support 27 is formed by a single printed circuit board 9 for a pair of first optical modules 22, 22 'or 23, 23'. This printed circuit board 9 serves to support the light source 51 of each of the first optical modules forming the pair. These light sources 51 are preferably electroluminescent diodes.

A cooling device 61 and the first support 27, in particular the printed circuit board 9, are connected together by a multiplicity of securing means 63, in particular screws. Referring to FIG. 7, it will be noted that the printed circuit board 9 may be interposed between at least one optical module, especially when it is made in one piece, and the cooling device concerned, the joining of these components. being then ensured by the multiplicity of securing means 63.

The description made above in relation to the first support 27 is of course transposable to the second support 28 which receives at least a second optical module 23, 23 '. Thus, the first optical modules 22 and 22 'which participate in the generation of a first light beam are united on a support different from that on which are joined the second optical modules 23, 23' which participate in the generation of the second light beam . According to a characteristic of the invention, the first support 27 and the second support 28 are mechanically connected to one another, advantageously by the multiplicity of securing means 63 mentioned above. The connection between the first support 27 and the second support 28 occurs at one end of these supports. Advantageously, the securing means also makes it possible to connect together the cooling device 61 assigned to a first support 27 and the second cooling device 61 assigned to the second support 28. FIG. 9 shows a fourth embodiment of the lighting device and or signaling 21 according to the invention. Its structure is similar to the third embodiment and reference will be made to FIGS. 7 and 8 and the description relating thereto to know the structure thereof. The following will describe the differences.

A first difference lies in the relative position of at least one first optical module 22 or 22 ', and advantageously of the pair of first optical modules, with respect to at least one second optical module 23, 23', advantageously to the pair of second modules optics.

At least a second module 23, 23 'generator of the second V-cut light beam is placed on a lateral side of at least a first module 22, 22' generator of the first plane-cut light beam.

According to an alternative, the first support 27 is connected to the second support 28 by one side thereof. It is thus understood that the pair of first optical modules 22, 22 'is placed on the side of the pair of second optical modules 23, 23' in a horizontal direction.

This connection may for example be implemented via the frame 75, the latter comprising a first portion 75a dedicated to the mechanical holding of at least a first optical module 22, 22 'and a second portion referenced 75b dedicated to mechanical maintenance at least one second optical module 23, 23 '. It will be noted that the first portion 75a and the second portion 75b may be two separate and distinct pieces. According to an alternative, these two portions installed side-by-side can be made in the form of a single piece. Figures 10 to 12 are applicable to the first, second, third and fourth embodiments.

The projection of the first light beam 14 generated by the first optical module or modules, on a screen (XX '; Y-Y') perpendicular to the optical axis ZZ 'of the lighting and / or signaling device according to the invention , is shown in Figure 10.

This has a large extent, located under the horizontal axis X-X 'and a cut 14.1 plane and parallel to said horizontal axis X-X'. In FIG. 11, the projection of the second light beam 15, generated by the second optical module or modules, on this same screen (XX ', Y-Y') has a smaller extent than that of the projection shown in FIG. 10, as well as a V-cut. This inclined cutoff comprises a first branch 15.1, located on one side of the screen with respect to the axis YY 'and parallel to the horizontal axis X-X', and a second branch 15.2, on the other side of the axis YY 'and rising above the horizontal axis XX' of a non-zero angle, for example between 8 ° and 15 °. The projection of the resulting light beam 50 generated by the entire lighting and / or signaling device, shown in FIG. 12, has, thanks to the first light beam 14, a large extent under the horizontal axis X-X ' which makes it possible to provide a very wide illumination for the comfort of the driver of the motor vehicle. This resulting light beam 50 also comprises a V-cut generated by the second light beam 15, the first leg 15.1 of which is located on one side of the screen (XX '; Y-Y'), is parallel to the horizontal X-X ', and the second branch 15.2, located on the other side of said screen, rises above the horizontal axis XX' of a non-zero angle. It has been found that an optimal arrangement of the first optical modules vis-à-vis the second optical modules allowing adequate absorption of the tolerance on the sharpness of the plane cut 14.1 of the first light beam 14 can be obtained when projected on the screen (XX '; Y-Y') perpendicular to the optical axis Z-Z ', the plane cutoff 14.1 of the first light beam 14 is located below the first branch 15.1 of the cutoff of the second light beam 15 at an angle between 0.3 ° and 0.6 °.

For the purpose of optimum illumination vis-à-vis the cost of manufacture of the device, each of the optical modules may for example comprise one or more light sources in the form of light-emitting diodes, preferably single-chip, all these diodes being advantageously arranged on the same side of the corresponding common support. Since all the optical modules of the lighting and / or signaling device according to the invention are formed by one of the assemblies described above, it follows that these different optical modules, whose structures are similar, can be manufactured in a standardized way, in series and by means of the same manufacturing tools, which makes it possible to reduce the costs of design and manufacture of such a device. The device 1 thus makes it possible to generate a code-type beam and can therefore be used to equip a motor vehicle headlight. Finally, note that the support, in particular called first support or second support, mentioned above is advantageously formed by a heat sink responsible for cooling the light source or the light sources of the optical module or modules concerned and / or the electronic components installed on the printed circuit board.

Claims (11)

REVENDICATIONS1. Lighting and / or signaling device (1, 11, 21), particularly for a motor vehicle, having an optical axis (Z-Z ') and comprising: - a first optical module (2, 2', 12, 12 ' , 22, 22 ') adapted to generate a first light beam (4, 14) having, in projection on a screen perpendicular to the optical axis (Z-Z'), a plane cut (4.1, 14.1), and - a second optical module (3, 3 ', 13, 13', 23, 23 ') adapted to generate a second light beam (6, 15) having, in projection on a screen perpendicular to the optical axis (Z-Z') , a cleavage comprising two branches (6.1, 15.1, 6.2, 15.2) forming between them a non-zero angle, said first and second optical modules (2, 2 ', 12, 12', 22, 22 ', 3, 3' , 13, 13 ', 23, 23') being arranged with respect to each other so that, in projection on a screen (XX '; Y-Y') perpendicular to said optical axis (Z-Z ') said light beams (4, 14, 6, 15) are at least partially superimposed, characterized in that said first and second optical modules (2, 2 ', 12, 12', 22, 22 ', 3, 3', 13, 13 ', 23, 23') are mounted on supports (7, 8, 17, 18, 27, 28) and each comprise: either the assembly of a collector (53) arranged to collect the light coming from a light source (51), a folder (54) having a cutoff edge for passing only a portion of the beam from the collector (53) and thereby producing a corresponding light beam and its cutoff, and ^ a reflector (71) arranged to produce forward said corresponding light beam (4, 14, 6, 15), or the assembly of: a collector (53) arranged to collect light from a light source (51), a folder (54) presenting minus one cutoff edge to allow passage of only a portion of the beam from the collector (53) and produce the corresponding light beam and its cutoff, and a lens (55) arranged for focusing the light beam from the collector (53), or a reflector (52) having a complex surface configured to collect the light from a light source (51) and for producing the corresponding light beam (4, 14, 6, 15) having a cut. 2. Device according to claim 1, wherein the first and second optical modules are arranged relative to each other so that, in projection on a screen (XX '; Y-Y') perpendicular to the axis optical (Z-Z '), the cutoff (4.1, 14.1) of the first light beam (4, 14) and one of the branches (6.1, 15.1) of the cutoff of the second light beam (6, 15) are parallel to a horizontal axis (X-X ') of said screen. 3. Device according to claim 2, wherein the first and second optical modules are arranged relative to each other so that, in projection on a screen (XX '; Y-Y') perpendicular to the axis optical (Z-Z '), the branch (6.1, 15.1) of the cutoff of the second light beam (6, 15), parallel to the horizontal axis (X-X') of said screen, is located above the cutting (4.1, 14.1) of the first light beam (4, 14). 4. Device according to claim 3, wherein, the cutoff (4.1, 14.1) of the first light beam (14) being blurred, the first and second optic modules are arranged relative to each other so that, in projection on a screen (XX '; Y-Y') perpendicular to the optical axis (Z-Z '), the fuzzy cut (4.1, 14.1) of the first light beam (4, 14) is included in the second light beam ( 6, 15). 5. Device according to claim 4, wherein the first and second optical modules are arranged relative to each other so that, in projection on a screen (XX '; Y-Y') perpendicular to the axis optical (Z-Z '), the cutoff (4.1, 14.1) of the first light beam (4, 14) is located below the limb (6.1, 15.1) of the cutting of the second light beam (15) at an angle between 0.3 ° and 0.6 °. 6. Device according to one of the preceding claims, wherein the two branches (6.1, 15.1, 6.2, 15.2) of the cutoff of the second light beam (6, 15) form between them an angle of between 8 ° and 15 °. 7. Device according to one of the preceding claims, wherein the cutoff of the second light beam (6, 15) is clear. 8. Device according to one of the preceding claims, wherein each support (7, 8, 17, 18, 27, 28) is formed by a printed circuit board (9) on which rests at least one light source (51) . 9. Device according to any one of claims 1 to 7, wherein there is provided a cooling device (61) in contact with the support (7, 8, 17, 18, 27, 28). 10. Device according to any one of the preceding claims, wherein at least one optical module comprises at least one light source (51) in the form of a single-chip light emitting diode. 11. Device according to any one of the preceding claims, arranged to participate in the production of a code function of a motor vehicle.