EP1835325A2 - Infrared lighting module for a vehicle headlight and headlight equipped with such a module - Google Patents

Abstract

The module has a dichroic mirror (3) placed at an intersection (4) of optical axes (X1, X2) of infrared and visible diodes (1, 2). The mirror is adapted to reflect infrared light and to pass visible light so that the infrared light creates a virtual light source that is adapted to be partially superimposed at the visible diode. The infrared light and the visible light transmitted by the mirror are focused in downstream of the mirror by a diffraction lens (5).

Description

Field of the invention

The invention relates to a multifunction light projector module for a motor vehicle, wherein one of the functions corresponds to the emission of an infrared light beam used in particular to illuminate a night road scene. This infrared lighting is associated with an infrared camera to perform a night lighting function (or Night Vision, in English terms).

The invention has applications in the field of the automobile and, in particular, in the field of night lighting for a motor vehicle.

State of the art

In the field of automotive lighting, there are different types of lighting devices among which we find mainly low position lights, low intensity and range, low beam, higher intensity and range on the road is about 70 meters high and the long-range high beam (around 200 meters). Conventionally, the low beam is used at night, in town or on the road when the vehicle crosses another vehicle. High beams are used on a road or highway when there are no other vehicles whose driver might be dazzled.

Conventionally, these different lights were obtained by means of several light sources integrated in the same projector. More recently, a dual-mode projector has appeared that can combine the functions of low beam and high beam. Such a two-mode projector is equipped with a single light source and a cover. This cover is generally a removable metal plate capable of passing from a first position in which it does not obscure the light beam produced by the light source to a second position in which it partially obscures this light beam. When the cover partially obscures the light beam, the headlamp is in the "dipped beam"function; when the cover is in its first position, the headlamp is in the "high beam" function.

Currently, there are projectors offering features that improve the lighting of the road, depending on particular situations.

For example, there is a Dynamic Bending Light (DBL) feature that tracks the vehicle's trajectory, improving the driver's visibility when cornering.

There is also a lighting compensation function that changes the lighting vertically depending on the attitude of the vehicle.

In addition, there are functions for improving the lighting of a vehicle, called AFS (Adaptive Front Lighting System) functions, which depend on the road situation, that is to say, the situation in which find the vehicle at a given moment. This situation may depend on the location of the vehicle, weather conditions, the road code adopted by the country in which the vehicle is located, etc.

One of these functions, called "townlight" in English, concerns city lighting. This function ensures a broadening of the light beam and a slight decrease in the range of each dipped beam, to spread the light beam produced at the front of the vehicle, to promote the illumination of side roads and sidewalks.

A function, called motorway or "motorway" in English, relates to motorway lighting. This function ensures an increase in the light range of the low beam when the vehicle is on a highway.

A function, called bad weather, also called adverse weather function in English, relates to lighting in bad weather. This function spreads the light beam of each dipped beam and a slight decrease in the light flux sent downwards, so that the driver of the vehicle, or those of oncoming vehicles, is not dazzled by the reflection of the projectors. on wet road.

There is also a function called night vision, which provides infrared illumination of a night road scene. The illuminated road scene is filmed using an infrared-type camera. The images produced by the camera are processed and displayed so that the driver can view, on a screen or directly on a portion of the windshield (via a head-up vision system designated in English by the term "Head Up Display" or HUD in abbreviation), the road scene located at the front of his vehicle.

These different functions are obtained separately by means of additional light sources and / or by changing the position of the cover in the projector. It is then understood that the implementation of several of these functions is complex. In addition, the implementation of some of these functions requires the addition of one or more additional light source (s), which increases the cost of a projector.

In particular, the night vision functions are obtained by means of an infrared lighting module specific to night vision. To insert this module into the projector, it is very often necessary to remove one or more elements already in place. Therefore, at the time of purchase of the vehicle, the owner of a vehicle must choose between the night vision function and another lighting function.

To solve this problem, there are two-function projectors combining both the infrared lighting function and the visible lighting function, especially in its road lighting function. In such a projector, of elliptical type, the light source is generally a single source, for example of the halogen type, equipped with a removable filter. This filter is a filter promoting the emission of infrared radiation; in other words, this filter passes only the infrared spectrum of the radiation emitted by the halogen light source. More specifically, when the filter is in a lowered position, the light source emits its visible radiation directly to the output of the projector. The projector then offers traditional street lighting. When the filter is raised, then only the infrared radiation of the light source is transmitted to the output side of the projector. The projector then offers infrared lighting. Thus, when the vehicle moves on a road with little traffic and no vehicle in the opposite direction, the driver can select a traditional road lighting. When a vehicle arrives in the opposite direction, the driver must switch to crossing lighting. In this case, it can select the crossover lighting alone or the night vision function by means of infrared lighting. This infrared illumination is then added to the crossing illumination, without being inconvenient for the driver of the oncoming vehicle since the radiation infrared is not visible for this driver. However, such a bi-function projector has a large footprint, namely the size of an elliptical projector. In addition, the life of a conventional light source, particularly a halogen-type source, is relatively short since a single filament light source is used for two functions namely the road function and the infrared function. In addition, an elliptical projector does not allow a very wide variation of style; in particular, it does not highlight the fact that it is an infrared illuminator and not a simple halogen road.

Presentation of the invention

The invention aims to overcome the disadvantages of the techniques described above by providing a multifunction module, whose light sources are diodes. For this, the module of the invention uses a light source with visible radiation and an infrared light source, each source being made by means of one or more diodes. The use of diodes makes it possible to reduce the bulk of the module. In addition, it allows to play on the style of the projector because of the small size of the diodes and their modularity. The module of the invention also makes it possible to increase the lifetime of the light sources by the fact that each type of lighting (infrared and visible) is generated by a different source. In addition, diodes are sources of great intrinsic life (because based on semiconductor materials).

• la première source lumineuse comporte au moins une première diode,
• la seconde source lumineuse comporte au moins une seconde diode, et
• ledit module comporte une surface de réflexion partielle placée à une intersection du premier axe optique avec le second axe optique et apte à réfléchir les premiers rayonnements lumineux et à laisser passer les seconds rayonnements lumineux de sorte que les premiers rayonnements lumineux créent, par réflexion sur la surface de réflexion, une source lumineuse virtuelle, située derrière l'élément réfléchissant, et apte à se superposer au moins partiellement à la seconde source lumineuse, les rayonnements transmis par la surface de réflexion partielle étant focalisés en aval par un moyen de focalisation.

More specifically, the invention relates to a lighting multifunction lighting module for a motor vehicle, comprising a first light source emitting first light radiation along a first optical axis and a second light source emitting second light radiation following a second optical axis,
such as :

• the first light source comprises at least a first diode,
• the second light source comprises at least a second diode, and
• said module comprises a partial reflection surface placed at an intersection of the first optical axis with the second optical axis and adapted to reflect the first light radiation and let the second light radiation so that the first light radiation create, by reflection on the reflection surface, a virtual light source, located behind the reflecting element, and able to be superimposed at least partially to the second light source, the radiation transmitted by the partial reflection surface being focused downstream by a focusing means.

According to the invention, the first diode and the second diode comprise a rectangular emitter, and in that the virtual image of the first light source formed by the partial reflection surface has at least one horizontal edge perpendicular to the direction of the optical axis of the focusing means.

Both sources emit radiation preferably in different wavelength ranges.

• l'une des sources lumineuse émet des rayonnements visibles et l'autre source lumineuse émet des rayonnements infrarouges.
• la surface de réflexion comporte un miroir dichroïque.
• le miroir dichroïque comporte une face d'entrée et une face de sortie, la face de sortie assurant une réflexion des premiers rayonnements lumineux.
• le miroir dichroïque comporte, sur sa face de sortie, une couche (ou un empilement de couches) apte à refléter les rayonnements infrarouges.
• le miroir dichroïque comporte, sur sa face d'entrée, une couche ou un empilement de couches) antireflet, notamment dans le visible, afin de limiter les pertes par réflexion des rayonnements visibles.
• les axes optiques des première et seconde sources lumineuses forment un angle sensiblement perpendiculaire.
• les axes optiques des première et seconde sources lumineuses forment un angle compris entre 80° et 120 ° ou entre 90 ° et 120°.
• la surface de réflexion est positionnée de façon à former un angle d'environ 45° avec chacun des axes optiques des première et seconde sources lumineuses.
• la surface de réflexion est positionnée de façon à former un angle avec chacun des axes optiques des première et seconde sources lumineuses approximativement égal à la moitié de l'angle entre les deux axes optiques.
• l'axe optique de la source de rayonnements visibles coïncide substantiellement avec un axe optique de la lentille.
• par exemple, dans le cas où l'on veut obtenir un faisceau ou une portion de faisceau de type autoroute (ou « motorway » selon la désignation en anglais), il est préférable que la surface émettrice de la diode émettant dans le visible soit disposée juste au dessus de l'axe optique du moyen de focalisation, à savoir celui de la lentille, notamment de façon à ce que son bord inférieur soit tangent à l'axe optique du moyen de focalisation, notamment une lentille. Exprimé autrement, en considérant la surface emittrice sous forme d'un rectangle, on préfère que l'axe optique de la diode émettant dans le visible soit au dessus de celui du moyen de focalisation de type lentille et disposé à une distance de celui-ci approximativement égale à la demi hauteur de la surface emittrice de la diode.
• la source lumineuse émettant des rayonnements visibles comporte une diode de lumière blanche.
• la face d'entrée du miroir dichroïque est non plane pour assurer une défocalisation de la source lumineuse émettant des rayonnements visibles.
• la surface de réflexion est amovible.

The invention may also include one or more of the following features:

• one of the light sources emits visible radiation and the other light source emits infrared radiation.
• the reflection surface comprises a dichroic mirror.
• the dichroic mirror has an input face and an output face, the output face providing a reflection of the first light radiation.
• the dichroic mirror comprises, on its exit face, a layer (or a stack of layers) capable of reflecting the infrared radiation.
• the dichroic mirror comprises, on its input face, a layer or stack of layers) antireflection, especially in the visible, to limit the reflection losses of visible radiation.
• the optical axes of the first and second light sources form a substantially perpendicular angle.
• the optical axes of the first and second light sources form an angle of between 80 ° and 120 ° or between 90 ° and 120 °.
• the reflection surface is positioned to form an angle of approximately 45 ° with each of the optical axes of the first and second light sources.
• the reflection surface is positioned to form an angle with each of the optical axes of the first and second light sources approximately equal to half the angle between the two optical axes.
• the optical axis of the visible radiation source coincides substantially with an optical axis of the lens.
• for example, in the case where it is desired to obtain a beam or a portion of a motorway-type beam (or "motorway" according to the designation in English), it is preferable that the emitting surface of the diode emitting in the visible be arranged just above the optical axis of the focusing means, namely that of the lens, in particular so that its lower edge is tangential to the optical axis of the focusing means, in particular a lens. Expressed otherwise, considering the emitting surface in the form of a rectangle, it is preferred that the optical axis of the diode emitting in the visible be above that of the lens-type focusing means and disposed at a distance therefrom. approximately equal to the half height of the emitting surface of the diode.
• the light source emitting visible radiation has a white light diode.
• the input face of the dichroic mirror is non-planar to ensure a defocusing of the light source emitting visible radiation.
• the reflection surface is removable.

The invention can be applied to any type of diode, in particular comprising a rectangular lambertian emitter placed in a plane orthogonal to the optical axis, behind a known primary optic, imposed by the manufacturer of the light emitting diode. The diodes may include a transparent protective dome located above the emitter, itself placed in the air. The diodes can also with a transmitter that is embedded in a clear transparent dome.

The invention also relates to a multifunction type light projector equipped with the module described above.

The invention also relates to a motor vehicle comprising a light projector equipped with such a module.

Brief description of the drawings

Figure 1 schematically shows a multifunction module according to the invention.

FIG. 2 represents the path of the visible and infrared light rays in the module of the invention.

Figures 3 and 4 show examples of a module according to the invention wherein the dichroic mirror is removable, allowing the realization of two or three lighting functions by this module.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

The lighting module according to the invention is a multifunction module having two light sources produced by means of diodes. This lighting module is intended to be installed in a light projector to achieve at least two lighting functions from the same module. This module can therefore be installed in a conventional projector, that is to say a projector whose shape is known, replacing a conventional light source such as a halogen source or any other light source generally ensuring the emission of light radiation in conventional projectors and, in particular, in elliptical projectors. The lighting module of the invention can also participate in the production of new projectors, with new shapes and styles, relating to the use of small diodes.

An example of a lighting module according to the invention is shown diagrammatically in FIG. 1. This module comprises two light sources, namely a source emitting visible radiation and another source emitting another type of radiation, preferably infrared radiation. . Each of these two light sources comprises one or more diode (s). For a better understanding of the invention, it will be considered in the remainder of the description, that each light source comprises a single diode, it being understood that it may comprise several grouped together with each other.

In the preferred embodiment of the invention, the first light source 1 emits infrared radiation. This light source will be called later infrared diode. The second light source 2 emits visible radiation. It will be called later visible diode. The path visible light R _v and infrared radiation R ₁ are shown in FIG. 2.

The infrared diode and the visible diode each emit radiation, respectively infrared and visible, along an optical axis specific to each diode. The optical axis X1 of the infrared diode 1 and the optical axis X2 of the visible diode 2 are not parallel and form an intersection 4. These two optical axes may be, for example perpendicular, as in the example of FIG. 1.

At the intersection 4 of these optical axes, the module comprises a partial reflection surface 3. This partial reflection surface 3 is a surface that has the particularity of reflecting certain radiation and let other radiation pass. As will be seen in more detail later, this partial reflection surface may be a mirror or any other selective reflection element, for example a diffraction grating. This partial reflection surface 3 will be called more simply, thereafter, mirror.

The radiation emitted by diodes 1 and 2 comes directly from the diodes. As the diodes are not associated with any primary focusing optics, the radiation emitted by the diodes is free, unfocused radiation. Light beams resulting from these radiations will be formed downstream of the mirror 3 by means of a focusing means 5 such as a diffraction lens. This focusing means 5, hereinafter referred to as the lens, ensures the focusing of the received light rays on its input face 5e. This focusing transforms light radiation into light beams with predefined characteristics. These light beams, infrared or visible, are directed towards the protective glass of the projector. Thus, whether they are visible or infrared, the light beams are formed by the same optics, namely the lens 5.

In the invention, the two diodes 1 and 2 as well as the mirror 3 and the diffraction lens 5 together form a lighting module. This lighting module is independent of other elements of the projector. This lighting module can therefore be installed in an existing projector, instead of a conventional light source, or in a new projector, created around this module.

As explained above, the radiation of the diodes 1 and 2 must be transmitted to the lens 5 to be focused. For this, the mirror 3 is placed at the intersection of the optical axes X1 and X2. In a preferred embodiment of the invention, the visible diode 2 is placed horizontally facing the lens 5. Its optical axis X2 is therefore coincident with the optical axis of the lens. The infrared diode 1 is placed vertically. Its optical axis X1 is perpendicular to the optical axis of the lens 5. The mirror 3 is then installed so as to form an equal angle between the optical axis of the visible diode 2 and the optical axis of the infrared diode 1 In this preferred embodiment, the mirror 3 is placed at an angle of approximately 45 ° to each of the optical axes X1 and X2.

It should be noted, however, that the infrared diode may be placed indifferently all around the optical axis of the lens 5. In the preferred embodiment of the invention, it has been chosen to place it below the optical axis, perpendicular to said optical axis, for manufacturing reasons and for thermal reasons (in order to best evacuate the amount of heat produced by these sources). In addition, when the light body of the diode is rectangular, it is desirable, for the constitution of an infrared beam of suitable shape by the lens 5, that the virtual image formed by the mirror has at least one horizontal edge (of preferably the edge of larger dimension), perpendicular to the direction of the optical axis of 5, which for a given position of the center of the diode requires to provide a proper orientation.

According to the invention, the mirror 3 reflects part of the received radiation. More precisely, it reflects one of the luminous radiations and allows the other luminous radiation to pass. For this, the mirror 3 may be a two-sided dichroic mirror, each face of which faces one of the two diodes. The dichroic mirror, in a preferred embodiment of the invention, has a flat surface for each of its faces. Its input face 3e, which faces the visible diode 2, ensures the passage of visible radiation. Its exit face 3s, which faces the infrared diode 1, is coated with a treatment layer capable of reflecting certain wavelengths and, in particular, the wavelengths corresponding to the infrared radiation emitted by the diode 1 So, the Dichroic mirror transmits the wavelengths corresponding to the visible light and reflects the wavelengths corresponding to the infrared light.

The visible light is therefore transmitted directly to the lens 5 while the infrared light is transmitted by reflection towards the lens 5. The reflection of the infrared radiation on the exit face 3s of the mirror 3 creates a virtual light source of the infrared diode 1. This virtual source of the infrared diode is placed on the optical axis of the lens 5, this optical axis corresponding to the optical axis X2 of the visible diode 2. The infrared radiation at the output of the mirror 3 are therefore on the same axis as visible radiation. In other words, the infrared virtual source is superimposed on the actual visible source. Thus, in the invention, a virtual image of a light source is created by a plane, this virtual image being placed at a predefined location.

Therefore, the infrared light beam obtained at the output of the lens 5 is similar to the visible light beam produced by the visible source. It is therefore possible, at the output of the lens 5, an infrared light beam or a visible light beam, both having the same spatial distribution.

The lighting module of the invention is associated with a means for supplying and controlling the light sources, not shown in the figures. Visible diodes 2 and infrared 1 are therefore controlled from this supply means which provides power to a single diode at a time or, in some embodiments, both diodes simultaneously.

In a preferred embodiment of the invention, the visible diodes 2 and infrared 1 are fed alternately. Thus, the lighting module emits either infrared lighting, when the user has switched the power supply means on the night vision function, or visible lighting, when the user switches the supply means on the visible function . Whatever the choice of the user, the light beam emitted by the lighting module, is similar geographically, that is to say that it is emitted in the same direction, with the same spatial characteristics.

In this embodiment, the distances between each of the diodes 1 and 2 and the mirror 3 are almost identical, which makes it possible to obtain, at the exit of the lens 5, a similar beam for the infrared and for the visible. It is Nevertheless, it is possible to place the infrared diode and the visible diode at slightly different distances, so that the virtual image of the infrared diode or the visible diode are, one or the other, away from the focus of the lens. It is thus possible to obtain a more or less narrow beam for one of the functions (the narrowest beam being that corresponding to the source (real or virtual) closest to the focus of the lens 5.

In the preferred embodiment of the invention, described above, the mirror 3 is a dichroic mirror with two flat faces, whose output face 3s is the reflecting face, covered with a treatment layer. This embodiment has the following advantage: the infrared emitted by the source 1 having a narrow spectrum, the treatment necessary to reflect the radiation of the infrared spectrum of the source 1 requires a smaller number of layers than the treatment necessary to reflect the visible spectrum from the source 2. This reflection of infrared radiation can be further improved by using as infrared source a monochromatic diode.

In this embodiment, the input face 3e can also be processed. It is then covered with an antireflection layer so as to avoid any reflection of the visible radiation so that a maximum of this radiation passes through the mirror 3.

In another embodiment, the infrared diode 1 is placed on the optical axis of the lens 5 and the visible diode 2 is placed perpendicularly to this optical axis. In this case, the output face 3s of the dichroic mirror 3 has a larger number of processing layers, because of the wider spectrum of the source 2. Indeed, since each treatment layer reflects a single wavelength, it is necessary to superimpose several treatment layers to reflect the different wavelengths of visible light.

In this embodiment, it is possible to choose, as a visible source, a white light diode. Indeed, the light emitted by such a diode is obtained from blue and yellow-green radiation. The white of this light is obtained by additive synthesis of these two colors in the diode. The reflection of the white light, by a dichroic mirror, is thus easier to obtain than that of the visible light since it only requires the covering by a layer reflecting the blue spectra and a layer reflecting the yellow-green spectra. In addition, since the white light of a white diode contains virtually no red radiation and since the infrared diode does not contain white light, then the realization of the dichroic mirror is relatively simple, i.e. it requires few layers if a thin-film interference-type solution is chosen because the selectivity of the reflector need not be large.

In another embodiment of the invention, the partial reflection surface 5 is made by means of a diffraction grating whose angular response depends on the wavelength. In this case, it is possible to choose two collimated beams associated with a prism.

In the embodiment of the invention described above, is associated in the same lighting module, the infrared function for night vision with the road function. However, the infrared function can be combined in the lighting module with the DRL daylight function or with the fog lamp function. In this case, infrared light and visible light can be emitted simultaneously.

In the case of the DRL function, the light beam obtained at the exit of the lens 5 must be more spread out, that is to say more diffuse than a driving beam, so as to emit a light beam at a distance less long but wider than road lighting. In this case, one can choose to give an additional function to the mirror 3 so as to deflect the visible diode radiation before they enter the lens 5. For this, it is possible to modify the input face 3rd mirror 3, that is to say the mirror face located on the side of the visible diode. This input face 3e of the mirror 3 is then no longer flat but on the contrary convex, which ensures a defocusing of the visible radiation to send further behind. In this way, the visible light beam, obtained at the output of the lens, is more spread out.

In the case of the fog function, the input face 3e of the mirror 3 can be modified in a relatively complex manner in order to allow spreading of visible radiation without suppressing the cutoff.

As explained previously, in the lighting module of the invention, the mirror 3 and the position of the sources 1 and 2 must be such that the virtual image of the reflected source is superimposed at least partially to that of the non-reflected source, without notable deformation. Indeed, the non-imaging lenses, such as the lens 5 used in the module of the invention, are calculated for planar and rectangular sources, perpendicular to the optical axis. It should be noted, in particular, that the visible source can be used as part of a code beam (for a conventional code function, a motorway function or "motorway" in English, or a bad weather function, also called adverse weather function in English ,) if the lens 5 was designed for this. In this case, the infrared beam, which must be either centered vertically or complementary to the visible beam with a covering, is produced by the code-type lenses with a shift of the images. Indeed, an axial shift as discussed above allows to play on the focus and sharpness of the images projected by the lens (and to remove a possible cut) and a vertical offset allows to place the beams.

Thus, when the virtual image of the infrared source is superimposed on the visible source, the lens 5 is optimized to create a good road beam from a rectangular source. We then have a visible road bi-function module and night vision, according to the preferred embodiment of the invention.

When the virtual image of the infrared source is formed in the plane of the visible source, but shifted downward, then the lens 5 is optimized to create a motorway beam (motorway or "motorway") from a rectangular source (intense beam that is to say, focused and thin, cut), the beam obtained from the virtual infrared source then being a concentrated band, without cut, passing above the horizontal and corresponding to the night vision function. We then have a dual-function module for highway lighting and night lighting.

In the case of a lens for a motorway function or "motorway" in English, that is to say if the beam is very concentrated and cut (small flat cut and very intense beam below), we increase a lot reach by adding it to the road beam. However, the fact that the lens creates a break would be inconvenient for the road function. Also, to make disappear the cut, one shifts the source so that the cut is not created. This deflocates in the vertical plane. This defocusing can be obtained by positioning the mirror. The invention thus proposes an embodiment in which the mirror 3 of the lighting module of the invention is movable.

This movable mirror, or removable mirror, can be placed in a function position and in a neutral position. In its position of function, the mirror is at an angle of 45 ° of the optical axes X1 and X2 of the two sources 1 and 2. In this position, the infrared radiation is usable. In its neutral position, the mirror is placed horizontally or offset in any other way. In this position, the lighting module is in visible road function. With a removable mirror, it is possible to make a tri-function module with DRL functions, road lighting, and infrared lighting. In this case, we choose a mirror with a domed entry face to achieve DRL lighting. When the mirror is in place, that is to say in its function position, and the visible diode is powered then the lighting obtained is DRL lighting with infrared lighting. When the mirror is in the neutral position, the infrared source is off. The lighting obtained is then a road lighting.

The use of a removable mirror allows to offer three functions with a single lighting module. It also makes it possible to avoid the losses due to the mirror (absorption, reflection and transmission of the visible light emitted by the white diode) in order to obtain a high performance visible road function at the photometric level.

In the case of a bi-function module, the presence of a removable mirror makes it possible to produce a less expensive module because the mirror used is a simple, non-dichroic mirror.

In the case of a removable mirror, a mechanical system ensures a movement of the mirror, either in translation or in rotation with respect to an axis of rotation Ω.

An example of a removable mirror, according to a rotation, is shown in FIGS. 3 and 4. More precisely, FIG. 3 shows the mirror in the operating position and FIG. 4 shows the same mirror in the neutral position. These figures show the diodes 1 and 2 as well as the mirror 3 actuated by actuating means 6.

In this example, the mobility of the mirror is obtained by rotation around the axis Ω. A displacement along an axis of rotation parallel to the edge A may be associated with it. Such a displacement is particularly interesting because it allows to completely clear the mirror without risk of interference with the optical elements.

The crimping angle to change from the neutral position to the function position may be less than or equal to 45 °. This folding angle can be small, since it is sufficient for the mirror 3 not to interfere with the light beam coming from the visible diode 2 and passing through the lens 5.

The actuating means 6 may be, for example, an actuator associated with a gear 7. This actuator may be a DC motor or a rotary or linear electromagnet. These actuating means may comprise a safety device providing the mirror a safety position in case of failure. This safety device may be a return means such as a torsion spring 8 placed on the axis of rotation Ω. In this case, during visible running operation (white diode energized, infrared diode unpowered), the actuator is continuously powered to maintain the mirror 3 in the neutral position. For the infrared route function (infrared diode energized and white diode not energized), the mirror is returned to the function position.

The actuating means may consist of a bistable system in which the actuator passes a hard point to the mirror, to switch from the neutral position to the function position, each of these positions being a stable position.

A detection system, by switch or other sensor, can be added to the actuating means to provide information on the position of the mirror so that, in case of failure, the assembly, or at least the visible source, can be de-energized .

Claims (14)

- Lighting multifunction lighting module for a motor vehicle, comprising a first light source (1) emitting first light radiation along a first optical axis (X1) and a second light source (2) emitting second light radiation following a second optical axis (X2), the first light source (1) comprising at least a first diode, the second light source (2) comprising at least a second diode, and said module comprising a partial reflection surface (3) placed at an intersection (4) of the first optical axis with the second optical axis and able to reflect the first light rays and to let the second light rays pass so that the first rays by reflection on the reflection surface, a luminous source creates a virtual light source located behind the reflecting element and able to overlap at least partially with the second light source, the radiation transmitted by the partial reflection surface being focused downstream by focusing means (5), characterized in that the first diode and the second diode comprise a rectangular emitter, and in that the virtual image of the first light source (1) formed by the partial reflection surface (3) has at least one horizontal edge perpendicular to the direction of the optical axis of the focusing means (5). - Module according to claim 1, characterized in that one of the light sources emits visible radiation and the other light source emits infrared radiation. Module according to any one of claims 1 to 2, characterized in that the reflection surface comprises a dichroic mirror. - Module according to claim 3, characterized in that the dichroic mirror has an input face (3e) and an output face (3s), the output face providing a reflection of the first light radiation. - Module according to claims 3 and 4, characterized in that the dichroic mirror comprises, on its output face (3s), a layer or a stack of layers adapted to reflect the infrared radiation. - Module according to claim 5, characterized in that the dichroic mirror comprises, on its input face (3e), a layer or a stack of layers, antireflection, especially in the visible. - Module according to any one of the preceding claims, characterized in that the optical axes (X1 and X2) of the first and second light sources form an angle of between 80 and 120 ° or between 90 and 120 °, and in particular a substantially perpendicular. - Module according to one of the preceding claims, characterized in that the reflection surface is positioned to form an angle with each of the optical axes of the first and second light sources equal to about half the angle between the two axes optical, in particular so as to form an angle of approximately 45 ° with each of the optical axes of the first and second light sources. Module according to any one of claims 2 to 8, characterized in that the optical axis of the visible radiation source coincides substantially with an optical axis of the focusing means. - Module according to any one of claims 2 to 9, characterized in that the light source emitting visible radiation comprises a white light diode. - Module according to any one of claims 2 to 9, characterized in that the emitting surface of the visible radiation emitting diode is disposed just above the optical axis of the focusing means, in particular so that its edge lower than tangent to said axis. - Module according to claims 2, 3 and 4, characterized in that the input face of the dichroic mirror is non-planar to ensure defocusing of the light source emitting visible radiation. Module according to any one of claims 1 to 11, characterized in that the reflection surface is removable. Multifunction light projector, characterized in that it comprises a module according to any one of claims 1 to 12.

Images