EP2436968A1 - Light-emitting device for an automobile headlight - Google Patents

Abstract

The device (1) has mask surfaces (12, 13) arranged to create respective cuts in a light beam e.g. fog lamp or dipped light beam, generated by the device. An optical element (2) includes a focal spot and a focal line located at intersection of cut edges of the mask surfaces. A reflection face of reflectors (6), the mask surfaces and the optical element are arranged so as to allow generation of the light beam with the cuts when a light source (5) i.e. LED, emits light, so that the beam is delimited by the cuts of the mask surfaces.

Description

The present invention relates in particular to a light emitting device. A preferred application relates to the automotive industry for the production of signaling and / or lighting devices, in particular vehicle headlamps.

• des feux de croisement, ou codes, d'intensité plus forte et de portée sur la route avoisinant les 70 mètres, qui sont utilisés essentiellement la nuit et dont la répartition du faisceau lumineux est telle qu'elle permet de ne pas éblouir le conducteur d'un véhicule croisé. Typiquement, ce faisceau présente une coupure en partie supérieure avec une portion horizontale, préférentiellement environ 0,57 degrés en dessous de l'horizon, afin de ne pas éclairer la zone dans laquelle devrait se trouver le conducteur d'un véhicule arrivant en sens inverse,
• des feux de route longue portée, dont la zone de portée sur la route peut atteindre 600 mètres, et qui doivent être éteints lorsque l'on croise ou suit un autre véhicule afin de ne pas éblouir son conducteur,
• des feux antibrouillard.

In the latter field, we know lighting modules or projectors, among which we find traditionally essentially:

• low beam, or codes, of higher intensity and range on the road of around 70 meters, which are used mainly at night and whose distribution of the light beam is such that it allows not to dazzle the driver. a crossover vehicle. Typically, this beam has a cut in the upper part with a horizontal portion, preferably about 0.57 degrees below the horizon, so as not to illuminate the area in which should be the driver of a vehicle coming in the opposite direction ,
• long-range headlamps with a range of up to 600 meters on the road and which must be switched off when crossing or following another vehicle so as not to dazzle its driver,
• fog lights.

More recently, partial illumination modes have been developed consisting of forming a selective beam with dark areas where at least some vehicles or people do not dazzle. Road lighting is improved with respect to only the code lights, while avoiding the inconvenience of excessive brightness for crossed or tracked drivers, a nuisance that would arise, for example, from traditional long-range high beam. Such a selective lighting function is still called ADB (acronym for the English Adaptive Driving Beam that can be translated adaptive driving beam).

The publication EP-A1-2 196 726 is part of this technology by forming a specific beam with vertical cut that can be added to the conventional code beam. Featuring an LED source (for light-emitting diode), a reflector and a vertical beam cutoff surface, the module of this document provides projection over a wide range of space in front of the equipped vehicle if although its use in conjunction with the code beam is not well controlled.

Similarly, the document FR-A1-2 942 020 describes a module comprising two subsets, each comprising a light source (an LED or a group of LEDs) for generating a code beam and a road beam respectively. The beam route is superimposed on the code beam, the limit of the road beam being fuzzy so as to form a resulting beam without discontinuity. This document provides for the formation of a so-called partial road beam, comprising a vertical cut. In addition to its complexity, the known module of this document suffers from the same disadvantages as that of the previous document.

The invention solves these disadvantages.

• un premier réflecteur comprenant une face de réflexion,
• une source de lumière,
• une première surface de cache agencée pour créer une première coupure dans le faisceau lumineux généré par ledit dispositif d'émission de lumière;
• une deuxième surface de cache agencée pour créer une deuxième coupure dans le faisceau lumineux généré par ledit dispositif d'émission de lumière;
• un élément optique comprenant un premier foyer et/ou une première ligne focale situé à l'intersection du bord de coupure du premier cache et du bord de coupure du deuxième cache ;

The object of the invention is a light-emitting device for generating a cut-off light beam, in particular for a motor vehicle, said device comprising:

• a first reflector comprising a reflection face,
• a source of light,
• a first cache surface arranged to create a first break in the light beam generated by said light emitting device;
• a second cache surface arranged to create a second break in the light beam generated by said light emitting device;
• an optical element comprising a first focus and / or a first focal line located at the intersection of the cutoff edge of the first cache and the cutoff edge of the second cache;

the reflection face of the first reflector, the first mask surface, the second mask surface and the optical element being arranged to allow the generation of a light beam having the first cut and the second cut when the light source emits light, so that the beam is delimited by said first cut and by said second break.

• la première coupure est une coupure latérale du faisceau, dont la direction moyenne est sensiblement verticale,
• la deuxième coupure est une coupure inférieure du faisceau, dont la direction moyenne est sensiblement horizontale,
• la direction moyenne de la première coupure et la direction moyenne de la deuxième coupure formant un angle compris entre 60 et 100 degrés, préférentiellement entre 80 et 95 degrés.

According to the invention,

• the first cut is a lateral cut of the beam, whose average direction is substantially vertical,
• the second cut is a lower cut of the beam, whose mean direction is substantially horizontal,
• the mean direction of the first cut and the average direction of the second cut forming an angle of between 60 and 100 degrees, preferably between 80 and 95 degrees.

The average directions are in particular the direction of the straight line closest to the cut in question (for example in the least squares sense).

Note that in the present application, the concepts of lower, horizontal, vertical, lateral or longitudinal are taken by considering the lighting device according to the invention positioned and oriented to generate the cut-off beam on road, for example the position and the orientation that he will have once mounted on a vehicle. The optical axis is preferably that of said optical element.

According to an exemplary embodiment, the light rays emerge from the reflector by an exit zone delimited by the edge of the first cover, the edge of the second cover, a portion of the front edges of the reflector define an exit zone of the light beam emitted by said device. . Preferentially, the boundaries of this output area define about one quadrant. Quadrant means that the exit section, defined by the boundaries of the exit zone, is included in an angular sector of about 90 degrees delimited by a substantially vertical line and a substantially horizontal line. Advantageously, the exit section is thus delimited by a vertical segment and a horizontal segment intersecting preferentially at right angles, and by a line such as a curve joining the ends of the segments, in particular formed by a reflective end.

By forming a very selective beam cutoff, light is sent from only one side of the optical axis, solely or very predominantly, above the horizon. It has been found that, in this way, this beam does not produce near light, in particular below the horizontal cut of a code beam, so that it does not increase the luminous intensity produced by the code beam. at a short distance from the driver of the equipped vehicle. Such an increase in intensity causes an excess of light close to the vehicle, which may hinder the driver. Indeed, because of the reaction of the driver's pupil, the latter may no longer perceive the range of the beam. In addition, his eyes may not be directed preferentially in the direction of driving. At the same time, by sending light on only one side of the optical axis, only or for the most part, above the horizon, the maximum intensity advantageously remains approximately at the height of the horizon, preferably at the height of a non-dazzling horizontal cut-off portion of a low beam, the optimum position for visibility.

According to one possibility, the intercepting surface comprises a first cache surface, for example located in a plane perpendicular to the optical axis. This surface blocks a portion of the rays reflected by the reflector and provides the side cut effectively. Preferably, this surface is oriented approximately vertically. It is not necessarily flat but can be concave or convex. Preferably, the first cache surface is configured to mask, at the outlet section, a lateral portion (such as half) of the reflector wafer. Wafer means the section at the edge of the reflector, oriented in a plane transverse to the optical axis, at the output of the light rays out of the reflector.

It optionally has a border delimiting vertically the output area. Said border may comprise a convex or concave profile, or be rectilinear.

The latter may be formed of a first border portion inclined downward towards the exit section and a second edge portion extending downwardly from the lower end of the first border portion so as to inclined towards the first cache surface.

The intercepting surface may also include a second cache surface extending from the exit section toward the light source. This surface blocks a portion of the rays reflected by the reflector and ensures the lower cut effectively. Preferably, this surface is oriented approximately horizontally. It can be flat but not necessarily. It can in particular be concave or convex. It can be reflective.

The first and second cover surfaces may be integrally formed, for example by one-piece folding. This piece may be sheet metal especially when the surfaces are formed by folding a piece in one piece. The sheet also has the advantage of resisting the heat resulting from the concentration of rays by the reflectors.

• la coupure inférieure du faisceau comprend une portion de coupure sensiblement horizontale située du côté de l'intersection de la coupure inférieure et de la coupure latérale.
• la coupure latérale du faisceau comprend une portion de coupure sensiblement verticale située du côté de l'intersection de la coupure inférieure et de la coupure latérale.
• le réflecteur a une section longitudinale, suivant l'axe optique, de profil sensiblement elliptique.
• un premier foyer du profil sensiblement elliptique est situé sur la source de lumière et le second foyer du profil sensiblement elliptique est situé à la fois sur le bord de coupure du premier cache et sur le bord de coupure du deuxième cache.
• la source lumineuse est agencée de manière à ce que les rayons lumineux qu'elle émet soient dirigés vers le bas autour de la direction verticale.
• préférentiellement la source lumineuse comporte au moins une diode électroluminescente.
• la source lumineuse présente un décalage latéral relativement à l'axe optique, du côté du positionnement de la première surface de cache et/ou du côté opposé à la zone de sortie.
• le premier réflecteur a une forme sensiblement de portion ellipsoïdale comportant un premier foyer et un second foyer ; il s'agit préférentiellement d'un portion de demi ellipsoïde, soit la portion d'une moitié d'ellipsoïde prise d'un côté de l'axe optique; préférentiellement le demi ellipsoïde est sectionné selon un plan sécant à l'axe optique.
• préférentiellement, le plan coupant la moitié de demi ellipsoïde est perpendiculaire à l'axe optique. Préférentiellement, ce plan passe au niveau du deuxième foyer de la portion ellipsoïdale.
• l'intersection des bords de coupure des premier et deuxième cache est située, suivant l'axe optique de l'élément optique, à la distance de tirage du dit élément optique.
• l'élément optique est dissymétrique par rapport à l'axe optique dudit élément optique.
• le dispositif d'émission de lumière comporte des moyens d'entraînement en rotation du dispositif selon l'invention suivant un axe de direction sensiblement vertical.
• le dispositif d'émission de lumière correspond à un premier dispositif d'émission de lumière et comporte un dispositif d'émission de lumière additionnel comprenant un élément optique additionnel.
• l'élément optique additionnel, par exemple une lentille, comporte une face d'entrée des rayons lumineux issus d'un dispositif d'émission de lumière additionnel et une face de sortie des rayons lumineux commune à l'élément optique du premier dispositif d'émission de lumière. Cela permet notamment d'avoir un module compact pour générer à la fois le faisceau avec les deux coupures et le faisceau émis par le dispositif d'émission additionnel, ce module présentant également un aspect extérieur homogène.
• la première surface et/ou la deuxième surface de cache sont la surface d'une pièce métallique.
• la première et la deuxième surface sont deux surfaces d'une pièce unique ; préférentiellement, a pièce unique est une tôle pliée.
• Le dispositif d'émission additionnel est configuré pour projeter un faisceau de type code ou une partie d'un faisceau de type code.

Other optional features that can be implemented in combination or alternatively are indicated below:

• the lower cut of the beam comprises a substantially horizontal cutoff portion located on the side of the intersection of the lower cutoff and the side cutoff.
• the lateral cut of the beam comprises a substantially vertical cutoff portion located on the side of the intersection of the lower cutoff and the side cutoff.
• the reflector has a longitudinal section, along the optical axis, substantially elliptical profile.
• a first focus of the substantially elliptical profile is located on the light source and the second focus of the substantially elliptical profile is located both on the cut edge of the first cover and on the cut edge of the second cover.
• the light source is arranged in such a way that the light rays it emits are directed downwards around the vertical direction.
• preferentially, the light source comprises at least one light-emitting diode.
• the light source has a lateral shift relative to the optical axis, the positioning side of the first cache surface and / or the opposite side to the exit zone.
• the first reflector has a substantially ellipsoidal portion shape having a first focus and a second focus; it is preferably a portion of half ellipsoid, the portion of an ellipsoid half taken from one side of the optical axis; preferably the half ellipsoid is sectioned along a plane secant to the optical axis.
• preferentially, the plane intersecting the half-ellipsoid half is perpendicular to the optical axis. Preferably, this plane passes at the second focus of the ellipsoidal portion.
• the intersection of the cut edges of the first and second covers is located, along the optical axis of the optical element, at the pulling distance of said optical element.
• the optical element is asymmetrical with respect to the optical axis of said optical element.
• the light-emitting device comprises means for rotating the device according to the invention along a substantially vertical axis of direction.
• the light-emitting device corresponds to a first light-emitting device and comprises an additional light-emitting device comprising an additional optical element.
• the additional optical element, for example a lens, has an input side of the light rays coming from an additional light emission device and an output side of the light rays common to the optical element of the first device; light emission. This allows in particular to have a compact module to generate both the beam with the two cuts and the beam emitted by the additional transmission device, this module also having a homogeneous exterior appearance.
• the first surface and / or the second cover surface are the surface of a metal part.
• the first and second surfaces are two surfaces of a single piece; preferentially, a single piece is a folded sheet.
• The additional transmitting device is configured to project a code-type beam or part of a code-type beam.

The invention also relates to a projector equipped with at least one device as introduced above. This device may be a first light-emitting device, the projector comprising an additional light-emitting device with an additional optical element separate from said optical element of the first light-emitting device, or even separated by a space. This additional transmission device is configured to project a code-type beam or a part of a code-type beam, which may according to the embodiments being arranged to be able to be actuated according to the turns.

The invention also relates to a lighting system comprising a first light-emitting device according to the invention and a second light-emitting device according to the invention, the first device being arranged so that its light beam is on the right. a side cut corresponding to its first cut, and the second device being arranged so that its light beam is left of a side cut corresponding to its first cut.

According to this system, the first and second devices are arranged so as to enable the method according to which the side-cut beams of these devices are positioned so as to create a shadow zone in a global beam comprising the beams emitted. by these first and second devices. This shadow zone is delimited on each side by a vertical cut of one of these beams, so that the first device according to the invention illuminates to the right of the shadow zone, the second device according to the invention. enlightening invention to the left of the shadow zone. This shadow zone can then be positioned on a vehicle tracking or arriving in the opposite direction. Preferably, these beams are moved laterally to follow the vehicle followed or in the opposite direction and / or follow the curves of the road, especially in bends.

According to this system, the first and second devices are arranged in such a way that, in the method mentioned above, the beams emitted by the first and second devices constitute with an upper cut-off beam, such as a dipped beam or fog lamp, a selective overall beam. The beams emitted by the first and second devices preferably have their lower cutoff which coincides with the upper cutoff of the upper cutoff beam, and illuminate above this upper break. The shadow zone can thus be moved above this upper cut-off, either solidarily to the upper cut-off beam, or preferably independently.

The invention also relates to a vehicle equipped with at least one device, a projector, and / or a system as introduced above.

• la figure 1 montre en perspective un exemple de réalisation de l'invention ;
• la figure 2 est une vue en coupe longitudinale schématique illustrant notamment le placement relatif de différents composants du dispositif ;
• la figure 3 est une vue partielle de face au niveau de la section de sortie ;
• les figures 4 et 5 sont des diagrammes, le premier schématique, le deuxième plus précis, de lignes isolux obtenues avec un faisceau produit par le dispositif ;
• les figures 6a et 6b sont des sections horizontales du dispositif selon l'invention, montrant des exemples de deux possibilités de réalisation de l'élément optique du dispositif selon l'invention ;
• les figures 7 et 8 sont deux vues en perspective illustrant l'implémentation du module de l'invention en association avec des moyens de génération d'au moins un autre faisceau et en particulier un faisceau code ou une partie de faisceau code.

Other characteristics, objects and advantages of the present invention will appear on reading the detailed description which follows, and with reference to the appended drawings given by way of non-limiting examples and in which:

• the figure 1 shows in perspective an embodiment of the invention;
• the figure 2 is a schematic longitudinal sectional view illustrating in particular the relative placement of different components of the device;
• the figure 3 is a partial front view at the exit section;
• the figures 4 and 5 are diagrams, the first schematic, the second most accurate, of isolux lines obtained with a beam produced by the device;
• the Figures 6a and 6b are horizontal sections of the device according to the invention, showing examples of two possible embodiments of the optical element of the device according to the invention;
• the Figures 7 and 8 are two perspective views illustrating the implementation of the module of the invention in association with means for generating at least one other beam and in particular a code beam or a code beam portion.

The terms "vertical" and "horizontal" are used in the present description to designate directions, including beam-cutting directions, in an orientation perpendicular to the horizon plane for the term "vertical", and in a parallel orientation. in terms of the horizon for the term "horizontal". They are to be considered in the operating conditions of the device in a vehicle. The use of these words does not mean that slight variations around the vertical and horizontal directions are excluded from the invention. For example, an inclination relative to these directions of the order of + or - 10 ° is here considered as a minor variation around the two preferred directions.

As represented in figure 1 , a projection module of the invention may comprise a light emitting device 1 associated with an optical element 2 along the optical axis 3 of the lens 2 which will be described below. Furthermore, the module of the invention may associate additional devices for projecting other beams alternately or in addition to the beam produced by the light emitting device 1 described in more detail below.

By way of a preferred example, this beam may be added to a code-type beam for operation in the so-called ADB lighting mode. For example, the assembly can be mounted on a turntable whose orientation in a vertical direction can adjust the adaptive lighting function.

Optical element 2 presented to figure 1 essentially consists of a predefined index lens carrying an inlet face 4a allowing the admission of the light rays coming from the light emitting device 1 into the lens and an exit face 4b through which the projection of the light is carried out. beam.

The case shown in the various figures is particularly suitable for installation in a projector at the front of a motor vehicle. In the illustrated examples, it is adapted for a projection on the left side of the latter, in the context of traffic on the right.

The light-emitting device 1 is substantially oriented along a longitudinal axis corresponding to the optical axis 3 of the lens 2. This optical axis 3 is advantageously positioned in a horizontal plane. We have shown in figure 1 an orthogonal coordinate system in which the direction x corresponds to that of the optical axis 3, the direction y corresponds to the direction transverse to the optical axis 3, that is to say in a preferred case, when the device is placed in its operating position of illumination of the road in a vehicle, a horizontal orientation and the direction z corresponds to an orientation transverse to the optical axis 3 preferably in a vertical direction.

The device 1 comprises a source 5 advantageously configured to emit light rays substantially downwards with a mean direction oriented along the z axis, preferably the vertical direction. The light source 5 may consist of one or more sources and more particularly of one or more light-emitting diodes (LEDs). In the case of a plurality of LEDs, it is advantageous to position them in the same plane. In the illustrated examples, this plane is nonlimiting way oriented along the horizontal. Note that according to some embodiments, this plane could be inclined, or almost vertical, especially in the case where the reflector collecting the rays of the source is replaced by a dioptric collector.

In the case of the example shown, the light source 5 consists of a single LED, for example with several semiconductor elements, positioned at a first focus 8 of the reflector 6, transversely to the optical axis 3 and in a horizontal plane with an orientation so that its emission is directed downwards.

The source 5 cooperates with a reflector 6 whose object is to collect the light from the source 5 to send it back to an outlet area 7 of the reflector that the light rays pass in the direction of the optical element 2. As a preferred , the reflector 6 is an element whose inner surface has a shape substantially ellipsoidal portion having a first focus 8 and a second focus 9 appearing particularly in figure 2 . The reflective surface of the reflector 6 makes it possible to return the downward directed light rays emitted by the source 5 substantially in the direction of a slice of the reflector 6 at which the exit zone 7 is situated. In the illustrated example, it is a half ellipsoid sectioned along a plane secant to the optical axis 3. Preferably, this plane is perpendicular to the optical axis 3. Preferably, this plane passes at the second focus 9. Note that the reflector 6 may adopt a shape slightly different from the ellipsoid shape without departing from the preferred framework of the embodiment of the invention described above. It may in particular have, along the optical axis 3, substantially elliptical profiles, the ellipses formed by the profiles being different depending on the section in question.

Above the reflector 6 of semi-ellipsoidal shape, one can find the ignition control device of the source 5 as well as any means of heat dissipation. These elements are not represented.

To achieve a well-defined beam emission, the present invention comprises one or more surfaces for intercepting a portion of the rays emitted by the source 5 and returned by the reflector 6. The interception surface (s) are configured in a specific manner so as to produce a lateral cut in a first preferably vertical direction and a lower cut, preferably perpendicular to the first advantageously in a horizontal direction, preferably at the level of the horizontal cut for the dipped beam, in particular 0.57 ° in below the horizon.

Before describing more precisely a preferred embodiment of the intercepting surface making these cuts, reference is made to the figures 4 and 5 , a preferred embodiment of beams from the device according to the invention. These beams are illustrated in projection on a vertical screen, for example 25 meters from the vehicle comprising the device according to the invention. So, the figure 4 has a vertical side cut line 18, and a horizontal lower cut line 17. The lateral cut-off 18 and the lower cut-off 17 delimit a beam of which isolux curves are shown, presenting a zone of maximum light intensity 16 near the intersection of the vertical axis z and the horizontal transverse axis 17, either in the longitudinal axis of the vehicle, and a decreasing intensity towards the outside. The beam is particularly limited since only one quadrant is illuminated. Note that a more or less clear transition can be made between lightness and darkness at the cutoff lines 18 and 17. As a preferred example, the vertical cut 18 is clear while the horizontal cutoff 17 can be considered more fuzzy (possibly not particularly rectilinear) so that the beam extends slightly below a horizontal line located at 0.57 ° below the horizon line. This fuzzy cut line can improve the fusion with another beam, for example of the particular code type or a beam participating in a code.

The figure 5 illustrates more precisely the isolux curves of a beam obtained with a transition between lightness and darkness at the level of the horizontal cut-off line 17 which is more fuzzy than at the level of the vertical cutoff 18. It is observed that the horizontal cuts 17 and vertical 18 although sharp are not rigorously straight but approaching it. For example, it is possible to define a first straight line 17 'closest to the first cutoff 17 (for example in the least squares sense) and also a second straight line 18' closest to the second cutoff 18. The direction of the first straight line 17 ', ie the mean direction of the horizontal cut 17, is preferably approximately horizontal for the first cut, then called "horizontal cutoff" 17. The direction of the second straight line 18 ', ie the mean direction of the horizontal cutoff 18, is preferably approximately vertical for the second break, then called "vertical cutoff" 18.

According to an alternative embodiment, the horizontal cut corresponds to a portion of the lower cut-off 17 of the beam situated on the side of the intersection of the lower cut and the lateral cut, this portion extending over at least 3 °, which corresponds to a horizontal cut of a length of about 5 meters to 100 meters. Similarly, the vertical cutoff corresponds to a portion of the lateral cutoff 18 of the beam located on the side of the intersection of the lower cutoff and the lateral cutoff, this portion extending over at least 2 °, which corresponds to a vertical cut from a height of about 3.5 meters to 100 meters.

An example of interception surface for horizontally and vertically delimiting such a beam is for example represented at Figures 1 and 2 . In these figures, the light rays coming out of the reflector 6 are framed by an outlet section 7 delimited by the edge of the front end (with respect to the direction of emission of the light by the device) of the reflector 6 and the surface interception consisting of a first surface 12 and a second surface 13 described below. Optionally, other surfaces may participate in the interception surface without departing from the scope of the invention. The first surface 12 is a cover surface for blocking a portion of the light rays, especially at the outlet of the reflector 6 and having an orientation substantially transverse to the optical axis 3, preferably in a vertical plane. The first surface 12 is for example opaque. As shown, the first cover surface 12 extends substantially over one half of the edge of the reflector 6 so as to form a symmetrical system between an output section 7 allowing the rays to pass and a section complementary to the output section. 7 relative to the section of the reflector 6 at which the rays are blocked.

Advantageously, the vertical edge of the first cache surface 12 delimiting the outlet section 7 vertically is not perfectly rectilinear. We have shown in figure 3 an advantageous example in which the profile of the edge is slightly concave in the direction of the outlet section 7. In the example shown, this concavity is achieved by forming a border comprising two portions 14, 15 in the nonlimiting straight example and joining together to define different sections of the first cache surface 12. Depending on the height of the first surface 12, a first section extends downwards with a progressive width entering the exit section 7. This first section is followed by a second section of degressive width delimited by the second edge portion 15. This particular profile is realized to the extent that it was found that it allowed to increase the sharpness of the vertical cutoff 18 of the beam so as to deviate slightly from a simple vertical segment the light rays at this level so as to compensate for the deformations related to the aberrations of the lens 2. As a preferred example, the inclination of the first portion 14 is 6 ° and that of the second portion 15 is -2.5 °. Furthermore, it is possible to slightly shift the edge of the first surface 12 relative to the optical axis 3, for example 0.25 mm so as to allow more light to pass to the lens. The figure 3 shows an example of relative position between the edge constituted by the first and second portions 14, 15 and the optical axis 3.

The intercepting surface further comprises a second cache surface 13 also illustrated in FIG. figure 1 and extending in a plane perpendicular to the plane of the first surface 12. The first surface 12 is preferably oriented vertically and the second surface 13 is advantageously oriented horizontally. The second surface 13 may be located in a plane comprising the optical axis 3.

The second surface 13, like the first surface 12, is used to intercept light rays reflected by the reflector 6 and which are not directed towards the output section 7. In this way, a second horizontal cut is defined. A first possibility is to make the second cache surface 13 absorbingly, not returning the light rays. However, an advantageous solution is to constitute the second surface 13 in a reflective way so as to increase the number of light rays that will exit through the outlet section 7.

Note that the first surface 12 and the second surface 13 may be made in two separate parts or from a single piece suitably folded including sheet metal. In this way, the industrial realization of the interception surface is optimized and the relative position of the first surface 12 and second surface 13 can be easily fixed. It is also possible to produce the surfaces in one injected part.

Note that according to an alternative embodiment of the present invention, it is also possible according to, to have a surface of the first cache oriented along the optical axis so as to form a vertical cut in the beam. Compared to the example of figure 1 , the cutoff edge would always be positioned vertically, but the surface of the first cover would extend vertically backwards toward the LED. In this case, the first surface could be reflective so as to optimize the amount of light able to exit the device through the outlet section 7.

The figure 2 shows a longitudinal section illustrating more precisely the relative positioning of the various components mentioned above. Thus, the first focus 8 and the second focus 9 of the elliptical profile surface of the reflector 6 are shown. The light source 5 is advantageously located at or near the first focal point 8. The distance 10 represents the focal distance separating the source 5 from the rear end of the reflector 6. The output section 7 is in turn realized substantially in line with the second focus 9. At this level is the first surface of 12 and an end of the second surface 13. The latter extends from the first surface 12 rearward towards the reflector 6. Advantageously, the free end of the second cache surface 13 stops at a distance the first focus 8 equivalent to the focal length 10.

The lens 2 of the light emitting device comprises an optical axis 3 and arranged so that its outer face 4b is remote from the pulling distance of the lens 11 relative to the second focus 9.

Advantageously, the lens is symmetrical along a vertical plane through which the optical axis 3 passes.

The lens may be a conventional lens whose entrance surface meets the exit surface.

According to a more advantageous embodiment, illustrated in Figures 6a and 6b , the size of the device is reduced, by using a lens whose shape corresponds to that of such a conventional lens, but which would have been cut by two vertical planes 100 and 101, located on either side of the axis 3 of the lens 2. The cut lens thus has in particular vertical edges 102 and 103. The "cut portion" of the conventional lens is illustrated in FIG. Figures 6a and 6b by dots 107 and 108. To simplify the representation, unlike the first cache surface 12, the second cache surface is not shown.

According to a variant illustrated in figure 6a , the cutting planes 100 and 101 are substantially symmetrical with respect to the optical axis 3.

In a preferred embodiment illustrated in figure 6b , the cutting planes 100 and 101 are offset laterally, so that the cutting plane 100 situated on the same side of the optical axis 3 as the first cover surface 12 is closer to the optical axis 3 than the other cutting plane 101. This makes it possible to further stress the useful part of the optical element 2, this part being able to generate the large width of the beam (the left part of the beam according to the example illustrated in FIG. figure 6b ).

Preferably, the distance between the cutting planes 100 and 101 is identical in the variant of the figure 6a and that of the figure 6b .

By way of example, the distance between the cutting planes 100 and 101 is of the order of 50 mm, and the difference between the two variants of Figures 6a and 6b is of the order of 7 mm.

In the example illustrated in the various figures, the lens 2 has been chosen with a convex 4b exit face and close to a toric surface portion. This form cut out a square envelope indicated above has the advantage of being easily integrated into the environment of the vehicle to be equipped.

Another variant of the invention consists in making a slight difference between the transverse position of the source 5 and the optical axis 3. For example, in the case of a light-emitting diode, a 0.5 millimeter offset from the source 5 to the portion of the reflector 6 at which the first cache surface 12 is located. This allows a part of the light to be displaced so as to increase the flow in the useful part. In general, this offset may be between 0 and 1.5 millimeters in a preferred manner.

Representatives Figures 7 and 8 two perspective views revealing an exemplary implementation of the device of the invention in combination with means for transmitting other beams.

Thus, is shown in these figures, a light emitting device 1 cooperating with an optical element 2, at least a part of which is common with an additional light emitting device 19. The additional device 19 may be a conventional device for the generation of a code beam. Advantageously, the device 19 emits light towards an input face 20 of an optical element whose output 4b is common with the previously described device. Thus, it forms a compact assembly whose size is limited and which, seen from the output face 4b is particularly unitary. Preferably, but in a nonlimiting manner, in order to avoid any interference between the rays emitted by the two devices 1 and 19, a partition 21 is advantageously formed at the output of the latter at the input phases 4a, 20. substantially flat and vertical partition, for example sheet metal, may be suitable.

In the case of an operation of the invention for a lighting mode of ADB type, the device 1 and the additional device 19 may act together, the additional device 19 being in this context preferably a device of the beam generation type. code. The device according to the invention can be mobile with respect to that of the additional device 19. For example, the beam emitted by the device 1 according to the invention can evolve above the horizontal cut of the code beam of the additional device 19, the cutoff horizontal beam of the device according to the invention moving horizontally along the horizontal cut of the beam of the additional module. The vertical cut 17 of the beam then moves horizontally. The device is then intended to be rotated so that the vertical cutoff is positioned on one side of a vehicle tracked or crossed, so as to illuminate next to the vehicle, without dazzling the driver.

Note that according to an alternative embodiment of the invention, when the device generating the beam according to the invention is integral with the additional device 19, the beam transmitted by the additional device 19 may be only part of the passing beam, the rest of this beam being made by fixed additional device.

The assembly may be mounted on a turntable comprising means for driving in rotation along a substantially vertical axis. On this plate, the device according to the invention can be mounted movably with respect to the additional device, in particular in horizontal rotation.

As a preference, the flux of the beam created by the device 1 is greater than or equal to 250 lumens. It is also advantageous that the maximum illumination of this beam is greater than 50 lux at 25 meters and that it is as close as possible to the intersection between the horizontal and vertical cutoff lines 17, 18. Still as a preferred in an ADB application, it is interesting that the overall extent of the beam is sufficient and in particular about 15 ° horizontally and at least 5 ° vertically.

Thus, the present invention makes it possible, without having an unacceptable impact on the luminous efficiency of the assembly, to form a very limited beam able to add up with a code beam, or with a beam corresponding to a code beam portion, of so as to produce a lighting at the front of the vehicle equipped with particularly high performance in terms of visibility and without disturbing the driver including a presence of too much near light. This advantageous result is produced without implying complex means additional to the device implementing the code beam. It will be noted in particular that the intercepting surface can be made in a simple manner, in particular from a single piece folded specifically. Similarly, the light emitting device 1 can be easily associated with the additional device 19 producing the code beam, all advantageously using common means at the optical assembly. This coupled embodiment further facilitates the height adjustment of the horizontal cut, so that the beam ADB and the beam code have the desired transition and in particular a quasi-continuous transition around a horizontal line for example at the height of the horizon.

Note that the vehicle equipped with the device according to the invention may also be equipped with a complementary module, also corresponding to a device according to the invention, on the other side of the front of the vehicle. In this case, the beam of one of the modules according to the invention comprises the illuminated area to the left of the vertical cutoff, for example as illustrated in FIG. figures 4 and 5 , the beam of the other module according to the invention comprising the illuminated zone to the right of the vertical cutoff, for example a beam symmetrical to that of the figures 4 and 5 relative to the plane containing X and Z. By acting on the position of the beams emitted by the two devices according to the invention, can then frame the vehicle by the vertical cuts of the beams, the illuminated areas being on either side of this vehicle.

even though Figures 7 and 8 have a clustered configuration of the light emitting device 1 and the additional code beam generating device, their realization can be separated. For example, a cross layout is possible (device 1 in a left vehicle projector and device 19 in the right projector) without departing from the scope of the present invention.

REFERENCES

1.

Light emitting device

2.

Optical element (the lens in the illustrated examples)

3.

Optical axis of the optical element

4a.

Input side of the optical element

4b.

Output side of the optical element

5.

Light source

6.

Reflector

7.

Section of exit

8.

First focus

9.

Second focus

10.

Focal distance

11.

Draw of the optical element

12.

First cache area

13.

Second cache area

14.

First portion of border

15.

Second portion of border

16.

Zone of maximum light intensity

17.

Horizontal cut line

18.

Vertical cut line

19.

Additional device

20.

Input side of the additional optical element

21.

Partition

Claims (15)

Light emitting device (1) for generating a cut-off light beam, in particular for a motor vehicle, said device comprising: a first reflector (6) comprising a reflection face, a source (5) of light, a first cache surface (12) arranged to create a first break in the light beam generated by said light emitting device (1); a second cache surface (13) arranged to create a second cut in the light beam generated by said light emitting device (1); an optical element (11) comprising a first focus and / or a first focal line located at the intersection of the cutoff edge of the first mask (12) and the cutoff edge of the second mask (13), - the reflection face of the first reflector (6), the first cache surface (12), the second cache surface (13) and the optical element (11) being arranged to allow the generation of a light beam having the first cut and the second break when the light source (5) emits light, so that the beam is delimited by said first cut and by said second break, characterized in that the first cut is a lateral cut of the beam, the average direction of which is substantially vertical, the second cutoff is a lower cutoff of the beam, whose average direction is substantially horizontal, - The average direction of the first cut and the average direction of the second cut forming an angle between 60 and 100 degrees, preferably between 80 and 95 degrees. Device according to one of the preceding claims, wherein the first cache surface (12) is oriented approximately vertically. Device according to one of the preceding claims, wherein the edge of the first cover (12), the edge of the second cover (13), a portion of the front edges of the reflector (6) define an exit zone (7) of the light beam transmitted by said device. Device according to one of the preceding claims wherein the second cover surface (13) is oriented approximately horizontally. Device according to the preceding claim wherein the second cache surface (13) is reflective. Device according to one of the preceding claims wherein the reflector (6) has a longitudinal section, along the optical axis (3), substantially elliptical profile. Device according to the preceding claim wherein a first focus (8) of substantially elliptical profile is located on the light source (5) and the second focus (9) substantially elliptical profile is located both on the cut edge of the first cover (12) and on the cutting edge of the second cover (13). Device according to one of the preceding claims wherein the source (5) comprises at least one light emitting diode. Device according to any one of the preceding claims, in which the optical element (2) comprises an input face (4a) of light rays passing through the output section (7) and an output face (4b), said device thus forming a projection module. Device according to one of the preceding claims wherein the intersection of the cut edges of the first and second covers (12 and 13) is located, along the optical axis (3) of the optical element (2), at the distance pulling (11) of the optical element (2). Device according to one of claims 9 to 10 wherein the optical element (2) is asymmetrical with respect to the optical axis (3) of said optical element. Device according to one of the preceding claims comprising means for rotating the device along a substantially vertical axis of direction. Device according to one of the preceding claims corresponding to a first light-emitting device and comprising an additional light-emitting device (19) comprising an additional optical element comprising an input face (20) of the light rays coming from an additional light-emitting device whose output face (4b) is common to the optical element (2) of the first light-emitting device. Device according to one of the preceding claims, wherein the first surface (12) and / or the second surface (13) cache are the surface of a metal part. Lighting system comprising a first device according to one of the preceding claims and a second device according to one of the preceding claims, the first device being arranged so that its light beam is to the right of a lateral cut corresponding to its first cutoff and the second device being arranged so that its light beam is left of a lateral cut corresponding to its first cut.

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