FR2913750A1 - OPTICAL MODULE FOR MOTOR VEHICLE PROJECTOR - Google Patents

Abstract

The module has main optical elements provided with a main LED (LP) and a projection optical system in a form of a lens (L) or a paraboloidal type reflector, and secondary optical elements provided with a secondary LED (LS1) associated with a collimator (C1) and with a folding mirror (M). The main and secondary elements respectively emit main i.e. motorway type beam, and secondary light beams. The mirror deflects the light emitted by secondary LED, by using the collimator, in a direction of the optical system, and avoids interception of light emitted by the main LED.

Description

Optical module for motor vehicle headlamp

  The invention relates to an optical module for a motor vehicle headlamp, giving at least one cut-off beam, of the type of those comprising a projection system, for example a lens, and a light source disposed for example behind the lens it is separated by air, the light source preferably comprising at least one light-emitting diode (which will also be designated below by the abbreviation LED (for Light Emitting Diode for the sake of brevity). relates in particular but not exclusively, according to a method of realization, to the LED module according to the European Patent EP 06 291 391.9 filed on 1 September 2006 in the name of Valeo Vision, incorporated by reference in the present application, which describes methods of constructing light projector modules providing a cut-off beam for a motor vehicle, comprising a lens and a light source di sposed behind the lens from which it is separated by air, the light source being formed by at least one light-emitting diode, such that the exit surface of the lens is chosen so that it can be connected in accordance with a smooth and continuous surface with the exit surfaces of similar neighboring modules, by determining the entrance surface of the lens so as to obtain the cut-off of the light beam without using an occulting cover. This patent application indeed describes different module variants using LEDs to obtain cut-off beams, and one variant, in a non-limiting way, is more particularly of interest to the present invention, namely the variant where the light-emitting diode is in direct view of its associated lens, and where the diode is preferably inclined with respect to the lens: they are thus found more completely vis-à-vis one another. Note that this inclination can be chosen at a positive or negative angle with respect to the optical axis, the two types of inclination for adjusting the thickness of the beam in a comparable manner. The modules of this type, illustrated in particular by FIG. 25A of the aforementioned patent, can be used as unitary modules for making a beam or a portion of beam with horizontal or oblique cutoff. If it is intended to emit a beam portion, it may be supplemented by another complementary beam emitted by a different and already known module, for example using conventional halogen or xenon light sources (or power LEDs). . It is thus possible to use this module so that its cut-off beam completes the beam code of an elliptical module bi function code / route, in particular to obtain a global beam type highway code. The invention also relates, according to another embodiment, to the LED module according to the French patent, deposited in France on June 23, 2006 under the filing number FR 06 05 677 in the name of Valeo Vision, which describes a module of motor vehicle headlamp, of horizontal optical axis, for giving a substantially rectangular cut-off beam, comprising: at least one light source in the form of a flat rectangular emitting diode, protected by a transparent element, and a reflector , of paraboloid type, with: - the light source which is inclined at an angle to the horizontal, and is arranged to be seen from the reflector (inclined, so that the light beam provided by the reflector is thin, the upper edge of the source being located in the vicinity of the focus of the reflector, and the reflector which has a determined surface so that certain light rays coming from the upper edge of the light source are reflected horizontally. In each of the embodiments illustrated above by prior patent applications, a problem is raised when the elliptical module goes into the road position. Indeed, if the emitted road beam perfectly fulfills the regulatory photometric grid, it can be considered that, even with the addition of the complementary LED highway code beam, the driver can feel a certain discomfort of vision, due to a lack of volume of the vehicle. road beam, especially in its height and in its width, for example above 5%. It has therefore been envisaged to supplement the road beam with an additional beam which would bring light into this upper zone. However, the projectors have a calculated volume at least, and adding yet another optical module dedicated to this function is rarely feasible easily without completely reviewing the design of the projector. The object of the invention is then to be able to provide an additional beam, in particular to complete a road-type beam in the upper part, without resorting to an additional optical module, without substantially increasing the space requirement of a projector containing, for example, example, a code / route module and an additional module type highway code (or, more broadly, any other module assembly to perform all regulatory functions expected from a motor vehicle headlight). The invention firstly relates to an optical module for a motor vehicle headlamp, which contains: main optical elements intended to allow the emission of a main light beam and comprising at least one main light source in the form of one or more light-emitting diodes, and at least one projection optical system; secondary optical elements intended to allow the emission of a secondary light beam, and comprising at least one, in particular at least two, secondary light sources in the form of electroluminescent diodes, each optionally associated with a collimating or collecting element of the light which they emit, and associated with at least one secondary reflecting and / or diffusing element for substantially deflecting all the light emitted by said secondary light emitting diodes; , possibly via their colloid elements imation / collection, in the direction of said projection optical system, said secondary reflecting and / or diffusing element substantially avoiding interception of the light emitted by the main light source. Within the meaning of the invention, it is understood by optical projection system one or more optical elements capable of creating a cut-off beam from a light source devoid of occulting element participating in the formation of the beam cutoff. Preferably, the projection optical system comprises an exit lens, in particular convex towards the front, and / or at least one reflector. The invention thus proposes a secondary beam to be generated by a module already present in the projector, keeping little or no the initial volume of the module volume, and using this given volume to further functionalize it with one or more other sources. bright. The challenge has been to ensure that the main optical elements, in fact those present in the module initially installed in the projector, are not disturbed in their operation by adding the necessary secondary optical elements and vice versa. Now it has been found, surprisingly, to make the two functions coexist in a limited volume, and to ensure that the module can emit simultaneously or alternately two beams not substantially disturbing each other. , while these, in particular according to one embodiment, pass through a common output lens which is one of the types of projection system mentioned above.

  We will not go into the details of the so-called main optical elements, we can refer to the aforementioned European patent for more details, or to the examples described below for the version using an output lens, according to a first embodiment. In general, they comprise the lens and the light source comprising at least one light-emitting diode, said diode being disposed behind the lens from which it is separated by air, the exit surface of the lens being entirely convex towards the light-emitting diode. before and as it can be connected in a smooth, continuous surface with the lens exit surfaces of similar neighboring modules, and the input surface of the lens is defined so that the module provides a cut-off light beam without intervention of an occulting cover, in particular vertical. The invention is therefore more particularly concerned with the variant where the main LED is in direct view of the output lens, without the need for a folding type reflective surface. A second embodiment of the main optical elements uses a projection system with at least one reflector. We can also refer to the French patent FR 06 05 677 for more details. In general, they comprise: an optical projection system in the form of a reflector, at least one light source in the form of a light emitting diode with a rectangular rectangular emitter protected by a transparent element, said reflector being of paraboloid type the light source being inclined at an angle to the horizontal, and is arranged to be viewed from the reflector in an inclined manner, so that the light beam provided by the reflector is thin, the upper edge of the source being located in the vicinity of the focal point of the reflector, and the reflector has a surface determined so that certain light rays coming from the upper edge of the light source are reflected horizontally. According to this second embodiment, the projection optical system in the form of a reflector may be associated with a reflecting mirror, and this reflecting mirror may also be the secondary reflective and / or scattering element of the secondary optical elements: thus has an optical element common to the main optical elements and the secondary optical elements. In the remainder of this text, we understand by top, bottom, lateral, upper, lower, etc. .... terms relating to the positioning of the element considered as it is arranged once in the module / in the projector in mounting position in the vehicle. The terms front and back refer to the positioning of the element as a function of the general direction of propagation of light from the inside to the outside of the module.

  With regard to secondary optical elements: -. Advantageously, according to the embodiment where there are several secondary light sources, they are distributed relative to each other so that the lightning cones they emit meet on the reflecting element and / or secondary broadcast. It is thus possible to have a distribution in a circle around the main light source, above, and / or on one of the sides, and / or below the main source. LEDs can be used with their supports and their associated means of individualized connection. Alternatively, it is possible to use a support common to all the secondary LEDs. This support may be of the flexible electronic support type, also known by the English term flexboard and comprising a set consisting of a planar and electrically insulating flexible support and flat metal conductors for providing electrical connections between electronic components, including LEDs but also any accessory element of the radiator type, mounting bracket, stiffener element ...

  Preferably, the main direction of emission of the secondary light source or sources is towards the rear of the module. This direction is in particular inclined downwards relative to the horizontal, particularly in the configuration where the secondary LEDs are arranged above the main source, or laterally, when the secondary LEDs are arranged laterally with respect to the main source. The secondary reflective and / or scattering element forwards these rays. Preferably, the main direction of emission of the main light source is towards the front of the module and it is inclined, especially upwards, relative to the horizontal. This particular configuration, detailed in the patent mentioned above, makes it possible to obtain a smaller light beam than if the main LED were exactly opposite the entry face of the lens (configuration where the emission direction of the LED is parallel to the optical axis of the module and not oblique). Advantageously, the secondary reflective and / or diffusing element is an element with a partly reflective and partly diffusing surface.

  A substantially reflective surface can be used, such as an aluminized surface as used to usually make headlamp mirrors. But it is interesting here to have a surface that is at least partially diffusing too. The ratio between reflection coefficient and diffusion coefficient can vary between 20/80 and 80/20, for example. To adjust the two coefficients, we can use a reflective surface and texture it to reduce its reflection and increase its diffusion in a controlled manner. By being at least a little diffusing, the element will be able to return the light of the secondary LEDs with a greater angular dispersion, which is the goal sought: it is here that the secondary beam rather gives an illuminated atmosphere in the upper part. of the photometric grid, so that it adds a light as light and widely distributed / spread as possible, especially horizontally, opposite bright light spots. Preferably, in the case where several secondary light sources are used, there is only one common secondary reflective and / or scattering element for all the secondary light sources. Alternatively, there may be individual reflective and / or scattering elements for the or each of the secondary light sources (these individual elements may make superfluous individual elements of collimation of the source or sources). The secondary reflective and / or scattering element may be a substantially planar element. This is the simplest configuration. It can also be curved, in particular curved in two different directions, in particular by being substantially convex.

  According to one embodiment, and especially in the case where it is common to all secondary sources, the secondary reflective and / or diffusing element is disposed in front of the main light source. Indeed, as a rule, the main light source will be disposed in or in the immediate vicinity of the focal plane of the lens, since it is sought that the beam obtained is properly focused. By arranging the secondary reflective and / or scattering element in front of the main LED, it is defocused with respect to the lens, which makes it possible to obtain a secondary beam voluntarily defocused and therefore more diffuse in its distribution. (The reflective and / or diffusing element can also be arranged behind the lens, but the forward configuration is preferred). The reflecting element and / or secondary diffusing element may have, especially in the case where it is common to all secondary sources and where it is placed in front of the main source, a cut-out allowing the light emitted by the main light source to pass: its presence does not interfere with the cone of light emitted by the main source. It may have an indentation, or even be in several parts around the main source.

  Advantageously, the secondary reflective and / or scattering element has, especially in the case where it is common to all secondary sources, an optically active surface at least below and / or on each side of the main light source. This arrangement makes it possible to obtain a secondary beam placed at the top of the photometric grid (with respect to a conventional road distribution) and wide. Advantageously, the collimation element or the light collection element of the secondary light sources is either a collector mirror surrounding each of the sources, or a collimator of light transmitting material. These collimators have a known operating mode, for example from US Patent 2006 0239020, equivalent to patent EP 1 715 245 in the name of Valeo Vision. An improvement to the known design is to further provide that its front surface is convex or concave, while in known systems it is generally flat. It can also be at least partially diffusing, be structured, be provided with diffractive means According to one embodiment, the main light beam from the main light source is a cut-off beam, in particular of the motorway code / complementary code type, in particular complementary to a code or road beam emitted by one or more other optical modules of the same projector.

  According to one embodiment, preferably associated with the previous one, the secondary light beam coming from the secondary light source or sources is a beam adding light above the main light beam. The invention also relates to the projector incorporating an optical module described above.

  The invention will be described hereinafter with the aid of nonlimiting examples illustrated by the following figures: FIG. 1 is a schematic representation of the main optical elements and secondary optical elements of a module according to a variant A of FIG. invention according to a longitudinal section in a vertical plane passing through one of the secondary LEDs, Fig.2 is a variant of Figure 1, FIG. 3 is a perspective view of the module according to FIG. 1, with all the secondary light sources shown, FIG. 4 is a view from above of the module according to FIG. 1, FIG. 5 is a view from outside the module. according to FIG. 1, FIG. 6 is a simplified representation of a variant B according to the invention, in which only a secondary source is represented, its associated reflecting means and the output lens, FIG. a variant C according to the invention, in which only a secondary source and its associated reflecting element are shown in a lateral configuration, FIG. 8 is a simplified representation (section) of a collimator of a secondary LED according to FIG. invention, 9 is a simplified representation of the isolux of the distribution of a road-type beam obtained by an elliptical module xenon lamp, FIG. 10 is a simplified representation of the isolux of the distribution of the combination of the road-type beam according to FIG. 7 and the highway code-type beam obtained with the main optical elements of the module according to FIG. 1; FIG. 11 is a simplified representation of the isolux of the distribution of the combination of the road-type beam and the highway-code-type beam obtained with the main optical elements of the module according to FIG. 1, as in FIG. 8, with, in addition, the contribution of the secondary beam emitted by the optical elements of the module according to FIG. 1. FIG. 12 is a schematic representation of the main optical elements and the secondary optical elements of another module according to the invention, in a perspective view FIG. 13 is a representation of the module according to FIG. FIG. 12, in cross-section along a vertical plane FIG. 14 is a representation of a variant of the module according to FIG. 12, in FIG. cross section along a vertical plane Fig.15 is a simplified representation of the isolux of the combination of the combination of the road-type beam and the highway code-type beam obtained with the main optical elements of the module according to FIGS. 12 and 13, with in in addition to the contribution of the secondary beam emitted by the secondary optical elements of the module according to FIGS. 12 and 13. The set of these figures is extremely schematic, and the elements represented do not necessarily respect the scale, in order to facilitate the reading. . Series 1 of examples using to emit the main beam a projection optical system with an exit lens, in accordance with the above-mentioned European patent application number EP 06 291 391.9 Figure 1 is therefore the representation, according to a longitudinal section in a vertical plane, optical elements of a module M according to a first embodiment of the invention: the main optical function is performed in accordance with what is described in the variant of FIG. 25A of the aforementioned patent EP 06 291 391.9: a main LED LP on its support. S is arranged inclined, for example here with an inclination angle of about 45 relative to the vertical, facing a lens L whose construction is also described in detail in this prior patent. The LED LP is therefore in an oblique plane with respect to the optical axis of the module M, which is a configuration intended to produce a beam of the motorway code type (called Motorway in English). It is briefly recalled that the lens L has a convex exit face, which can be connected smoothly with the exit surfaces of any adjacent similar modules, and whose entrance surface is constructed to obtain a cutoff without using occultant cover. - The secondary optical function is performed with three secondary LEDs LS1, LS2, LS3. Figures 3 (a perspective view) and 4 (a top view) can represent these three LEDS. It should be noted that, alternatively, it is possible to use only one secondary light source: an LED is chosen which has a suitable power, which is higher. This single LED can also be placed above, sideways or below the main LED. The three secondary LEDs according to FIGS. 1, 3 and 4 are each attached to an individual support not shown and associated with a collimator made of transparent material intended to collect the light emitted by the LEDs. An example of a non-limiting collimator shape C is shown schematically in FIG. 8: the collimator has the approximate shape in the form of a hat or a cone. It is a room full of revolution, with a FE light entry face which has an enveloping shape comprising a hollow delimited by two side walls PL and a bottom wall convex PF. The emitting surface of the LED is arranged facing / at least partly in this hollow. The outlet face FS is slightly curved, convex, preferably cylindrical (alternatively, it could be flat). This specific form of the exit face makes it possible, in particular, to better spread out the beam coming from the secondary LEDs coming out of the lens L As shown in FIGS. 1, 3 and 4, the secondary LEDs Ls1, Ls2 and Ls3 and their collimators C1, C2 and C3 associated are arranged above the main LED Lp. They are arranged in a ring, so that the light emerging from their collimators converges towards a mirror M of reference. This mirror is flat. It is arranged in an oblique plane at 45, as the plane in which is disposed the main LED LP, plane shifted slightly forward with respect to the plane of the LED Lp. This mirror M has a U-shape, with a notch appropriate so that it does not intercept (or almost no) the light emitted by the main LED Lp. FIGS. 3 and 4 show, for each of the secondary LEDs, the outline of a radius according to each of their main direction of emission: it can be seen that these three rays converge towards the mirror M and that the mirror returns them towards the lens L. mirror is a sheet (alternatively a plate of polymer material) covered with a layer of aluminum. The layer has been deposited in such a way that it has a reflection coefficient of about 70% and a diffusion coefficient of about 30% (a ratio that can be broadly adjusted if necessary). The modification of the diffusion coefficient can in particular be obtained by using surface texturing. The mirror can also be streaked. Returning to Figure 1: only the central secondary LED is shown in section. Represented in this figure: on the one hand the limits of the light cone emitted by the main LED Lp, on the other hand, three limit radii of the secondary LED Ls2. A first dashed ray r1 corresponds to the last lateral ray coming out of the collimator returned to the mirror M. A second dashed ray r2 is the limit ray corresponding to the front edge of the collimator. A third radius r3 in solid lines corresponds to a central radius (like those represented in FIGS. 3 and 4).

  Figure 2 is a variant of the module according to Figures 1; 3 and 4: the plane p2 in which the mirror M is located is offset by an angle α of for example 5 or 10 with respect to the plane of the mirror p1 according to FIG. 1. Radius lines of FIG. 2 (with the same conventions as for FIG. 1) that this modification of inclination of the mirror modifies the orientation of the rays of the secondary LEDs at the exit of the lens L. The radius r'3 is represented with the mirror according to the inclination initial to 45 according to the plane p1, and r'2 with the mirror according to the inclination modified according to the plane p2: we see that r'3 leaves the lens higher than r3. The modification of the disposition, the inclination, the shape, the reflective / diffusing power of the mirror M make it possible to adjust the distribution and the general orientation of the light emitted by these secondary LEDs at the lens outlet, in accordance with the needs. very precise.

  The mirror may indeed not be strictly flat, although this form is the simplest to achieve. The mirror may also, for example, have a curved surface, convex or concave: It can be judiciously deformed to adjust the secondary beam. FIG. 5 is a representation of the module, seen from the outside of the module: the lens which closes the module towards the front, the three support plates Sp of the three secondary LEDs in the upper part, and the inclined plane p1 according to FIG. which the deflection mirror M is arranged: it is seen that it has been possible to add secondary LEDs and their optical means associated with the initial module, without the size of the module being substantially increased, and without them interfering optically with the beam emitted by the main LED LP. (the possible means of cooling of the type radiators of the LEDs have not been represented). FIG. 6 is an alternative embodiment: each secondary LED, like that represented by Ls1, is no longer associated with a collimator, but with a reflector R in one or more parts, which envelops the cone of light emitted by the LED for return to the reflecting mirror M. The reflector R may further be provided with ridges. And there is no reflecting mirror: the individual reflectors R directly direct the light of the secondary LEDs to the lens L.

  Figure 7 is an alternative embodiment: in this amplified representation of the module, the secondary LEDs are not arranged above, but on one side of the main LEC) LP. And the deflection mirror M is then arranged opposite the cones of light emitted by the secondary LEDs via their collimators or individual reflectors.

  We can of course also consider that secondary LEDs are arranged under the main LED, or even behind the main LED. In the latter case, we can then even remove the mirror, but this configuration is generally less suitable for module congestion issues (especially in depth), we want to minimize here compared to the initial module without secondary LEDs . FIGS. 9, 10 and 11 are representations of isolux: FIG. 9 is an isolux of a road-type beam emitted by an elliptical-type xenon-type road module, in known manner, module intended to be integrated in the same projector as the module according to the invention, - Figure 10 is the addition, compared to the isolux of the figure there, the highway code contribution obtained by the main beam emitted by the main LED Lp of the modulus according to FIG. 11 adds to the isolux of FIG. 10 the contribution of the secondary beam emitted by the three secondary LEDS of the variant according to FIG. 1 of the present application. From their comparison, we can draw the following conclusions: with the road beam according to Figure 9, the maximum intensity reaches a hundred lux. With the motorway code contribution according to Figure 10, the set is raised by about 1.5%, to bring the maximum intensity to about 150 lux in the axis. This superposition of beams is described in particular in the patent filed on June 19, 2006 in France under the filing number FR 06 05 431 in the name of Valeo Vision, to which we will refer for more details. With the addition of the contribution of the secondary LEDs according to FIG. 11, we see a fairly diffuse light input at the upper part of the grid above the dome which delimits the road beam according to FIG. 9: the secondary LEDs thus bring a light diffuses widely spread horizontally at the top, which significantly increases the comfort of vision of the driver, rather than having a very dark upper area sharp with the dome strongly illuminated road beam. . Series 2 of examples using to emit the main beam a projection optical system with a reflector, in accordance with the aforementioned patent application FR 06 05 677 FIG. 12 is a schematic representation of such a module, including the main optical elements are of the type described in Figure 4 of this patent, to which reference will be made for more details. The main LED LF ', a reflection mirror M and a paraboloidal reflector RP are represented. The LP diode 35 is disposed in a substantially horizontal plane, in front of the reflector RP. It is preferably provided with a transparent element, in the form of a dome or not. The mirror M is a plane mirror which gives the LP diode a virtual image which constitutes the light source for the reflector RP. A secondary LED Ls1 has been added according to the invention, arranged so that its emitting surface sends at least a portion of the light that it emits to the mirror M. The mirror M thus returns to the reflector RP at a time the light emitted by the main LED LP and the secondary LED Lsl. The reflector RP redirects the received light to the front of the module. So here we have a configuration where an optical element, the reflecting mirror M, is common to the main function and the secondary function.

  FIG. 13 details the path of rays emitted by LP and by Ls1: two radii Ipl and Ip2 emitted by the main source LP, which are returned by the reflector RP in substantially horizontal or descending directions - a ray Is1 emitted by the source secondary Lsl, which, when reflected by RP, has a significantly rising direction. FIG. 14 is a variant of the module according to FIGS. 12 and 13: the difference lies in the arrangement of the secondary LED Ls1: here it is arranged behind the main LED LP and in an oblique plane and provided with a collimator C. The system thus collects more light from Lsl than in the previous configuration. Figure 14 shows the paths of two rays from LP: Ip1 and Ip2, and the path of two rays from Lsl: Isl 'and Is2. It is seen from these ray paths that light from Lsl has a tendency, at the output of the module, to have a rising direction.

FIG. 15 is a representation of the isoluxes of the superposition of the road beam of the previous elliptical xenon module, of the highway code beam made with LP, and of the secondary beam obtained with the LED Ls1: the LED Ls1 adds light above the dome from the road in the Zi zone. Note that all the examples described above use in LED 30 main and secondary LEDs of LEDs white light (or possibly yellow), which is the regulatory color for the code beams.

Claims (9)

  1. Optical module (Mo) for a motor vehicle headlight, characterized in that it contains: main optical elements intended to allow the emission of a main light beam and comprising at least one main light source (LP) under one or more light-emitting diodes, and at least one projection optical system, secondary optical elements intended to allow the emission of a secondary light beam, and comprising at least one, in particular at least two, secondary light sources in the form of an electroluminescent diode (s) (Ls1, Ls2, Ls3) each associated with a collimation element (C) or a collection element (R) of the light which they emit, and or at least one secondary reflecting and / or scattering element (M) for substantially deflecting all the light emitted by said secondary light emitting diodes, possibly via their elements collimation / collection device, in the direction of said projection optical system, said secondary reflecting and / or diffusing element substantially avoiding the interception of the light emitted by the main light source (LP).   2. Optical module according to the preceding claim, characterized in that the projection optical system comprises an output lens (L), in particular convex forward, eiIou or at least one reflector (RP).   Optical module according to one of the preceding claims, characterized in that the main optical elements comprise a projection optical system in the form of a lens (L), and the light source comprising at least one light-emitting diode (LP). ) t disposed rearward of the lens from which it is separated by air, the exit surface of the lens being entirely convex forward and as it can be connected in a smooth and continuous surface with the surfaces of lens output of similar neighboring modules, and the input surface of the lens is defined so that the module gives a light beam cut without intervention of an occulting cover.   Optical module according to one of the preceding claims 1 or 2, characterized in that the main optical elements comprise -. an optical projection system in the form of a reflector (RP), -. at least one light source in the form of a planar rectangular emitter diode protected by a transparent element (LP), - said reflector (RP) being of paraboloid type, - the light source (LP) being inclined at an angle relative to horizontally, and is arranged to be viewed from the reflector (RP) in an inclined manner, so that the light beam provided by the reflector is thin, the upper edge of the source being located in the vicinity of the reflector focal point ( RP), and the reflector (RP) has a surface so that certain light rays coming from the upper edge of the light source (LP) are reflected horizontally.   5. Optical module according to one of the preceding claims, characterized in that the main optical elements comprise - a projection optical system in the form of a reflector (RP) associated with a reflecting mirror (M), - said mirror of return (M) also being the secondary reflective and / or scattering element (M) of the secondary optical elements.   6. Optical module according to one of the preceding claims, characterized in that there are several secondary light sources (Lsl, Ls2, Ls3) distributed relative to each other so that the light they emit 25 meets the reflective and / or secondary scattering element (M).   7. Optical module according to one of the preceding claims, characterized in that the main direction of emission of the light source (s) (Lsl, Ls2, Ls3) secondary (s) is rearwardly of the module, in particular being inclined downwards with respect to the horizontal or laterally.   Optical module according to one of the preceding claims, characterized in that the main direction of emission of the main light source (LP) is towards the front of the module and in that it is inclined, in particular upwards. , 35 with respect to the horizontal.   9. Optical module according to one of the preceding claims, characterized in that the secondary reflecting element and / or diffusing element (M) is an element with a surface for reflecting part and partly diffusing. Optical module according to one of the preceding claims, characterized in that there are several secondary light sources (Ls1, Ls2, Ls3) and in that there is only one reflecting element and / or common secondary scattering (M) for all secondary light sources or individual reflective and / or scattering elements (R) for each of the secondary light sources. Optical module according to one of the preceding claims, characterized in that the secondary reflecting and / or diffusing element (M) is common to all the secondary light sources (Ls1, Ls2, Ls3), and preferably disposed in front of the main light source (LP). Optical module according to one of the preceding claims, characterized in that there are several secondary light sources (Ls1, Ls2, Ls3) and in that the secondary reflecting and / or diffusing element (M) is common to all secondary light sources and has a cut-out allowing the light emitted by the main light source (LP) to pass. Optical module according to one of the preceding claims, characterized in that there are several secondary light sources (Ls1, Ls2, Ls3) and in that the secondary reflecting and / or diffusing element (M) is common to all secondary light sources and has an optically active surface at least below and / or on each side of the main light source (LP). Optical module according to one of the preceding claims, characterized in that the element for collimating or collecting light from the secondary light source (s) (Lsl, Ls2, Ls3). is a collector mirror (R) surrounding the or each of the sources, or a collimator (C) of light transmitting material 15. Optical module according to one of the preceding claims, characterized in that the collimation element of the secondary light source (s) is a collimator (C) with a flat, convex or concave front surface, and / or has a front surface that is at least partially diffusing, structured or 16. Optical module according to one of the preceding claims, characterized in that the main light beam from the main light source (LP) is a cut-off beam, in particular of the motorway code / complementary code type, especially complementary to a fai code or road seal issued by another optical module of the same projector. 17. Optical module according to one of the preceding claims, characterized in that the secondary light beam from the secondary light source (s) (Lsl, Ls2, Ls3) is a beam adding the light above the main light beam. 18. Projector incorporating an optical module (MB) according to one of the preceding claims.