EP3396237A1 - Light module for a motor vehicle - Google Patents

Abstract

A light module (1) for a motor vehicle comprises at least two light sources (2, 4), optical deflection devices (6, 8) for the light rays emitted by the light sources (2, 4), an optical arrangement for form (10) deviated rays, and a cover (12, 112) arranged between the optical deflection devices and the shaping optics and adapted to take at least two distinct positions.

According to the invention, the light sources (2, 4) are controlled according to the position of the cover (12, 112).

Description

The invention relates to the field of lighting and / or signaling, especially for motor vehicles.

A motor vehicle is equipped with headlamps, or headlights, intended to illuminate the road in front of the vehicle, at night or in the case of reduced luminosity. These headlamps can generally be used in two lighting modes: a first mode "high beam" and a second mode "low beam". The "high beam" mode provides strong illumination of the road far ahead of the vehicle with a focused beam around the optical axis of these projectors. The "dipped beam" mode provides illumination far away from the road, but nevertheless offers good visibility, without dazzling other road users, with a beam spread on both sides of the optical axis and under the light. skyline. These two lighting modes are used alternately depending on the traffic conditions encountered by the vehicle, and they are successively implemented by a manual control of the vehicle or automatically by a suitable control device.

It is known to produce the beams relating to the "high beam" and "low beam" modes through two separate modules, these modules being grouped together in the same projector.

Furthermore, there are known light modules in which two sources or sets of light sources are provided to achieve with a single module both a low beam function and a fire route function, which limits the number of modules and therefore the overall size of the light means to implement to achieve this plurality of functions. When it is desired to emit a beam of passing light, a first source is turned on and a cover cuts off part of the rays emitted to respect the shape of a first beam, of the cut-beam type, that is to say a partial beam illuminating the road scene as close as possible to the vehicle, with no rays emitted beyond the horizon line. When it is desired to emit a Route beam, it is necessary to switch on both sources simultaneously, so as to form the first beam as previously described via the first source and a complementary beam through the second source.

A disadvantage of such a solution is the presence of a dark bar between the first beam forming "low beam" and the complementary beam forming "high beam", the dark bar corresponding to the free end edge of the cache. The overall beam formed by the superposition of the two half-beams is not continuous and this can generate discomfort for the driver.

Other problems arise such as the luminous contrast between the part of the code beam whose light intensity is defined by the characteristics of a first light source, and the part of the beam forming the road, the light intensity of which is defined. by the characteristics of a second light source.

The second light source must be sized to emit high intensity light rays. Particularly in the case of a second light source formed of light-emitting diodes, it is then appropriate to dedicate many of these diodes to the road function, while this function is implemented less often than the code function.

The present invention aims to propose a light module that provides a solution to these various disadvantages.

For this purpose, the invention aims at providing a light module for a motor vehicle comprising at least two light sources, a device for deflecting the light rays emitted by the light sources, an optical shaping of deviated rays, and an arranged cache. between the deflection device and the shaping optics and adapted to take at least two distinct positions. According to the invention, the light sources are controlled according to the position of the cache. In particular, it can be provided that the switching on or off of the light sources depends on the position of the cover, or that the luminous flux of these light sources changes according to this position of the light source. hidden. It is thus known, by a simultaneous control of these two components of the light module, to propose a single module configured to project two types of beams, without a dark bar being present in the beam in "driving beam" mode.

• les sources lumineuses sont pilotées indépendamment l'une de l'autre en fonction de la position du cache ;
• le module lumineux comporte un module de pilotage de l'allumage des sources lumineuses configuré pour recevoir une information en provenance d'un module de commande du cache ;
• le module de commande du cache est configuré pour donner instruction à un mécanisme d'entraînement du cache de manière à positionner ledit cache dans une première position d'obturation partielle, dans laquelle une partie des rayons émis par les sources lumineuses est bloquée par le cache, ou dans une deuxième position de dégagement, dans laquelle aucun, ou tout au plus une quantité faible en regard de la partie des rayons bloquée par le cache dans la première position, des rayons émis par les sources lumineuses n'est bloqué par le cache ; par faible ou petite quantité de rayons par rapport à la première partie, on comprend que tout au plus 10% de la quantité de rayons correspondant à la première partie est bloqué par le cache dans la deuxième position de dégagement ;
• le dispositif de déviation comporte une pluralité de réflecteurs respectivement associés à l'une des sources lumineuses ;
• le dispositif de déviation comporte deux réflecteurs agencés l'un après l'autre le long de l'axe optique ;
• le dispositif de déviation comporte au moins deux réflecteurs agencés l'un à côté de l'autre, transversalement à l'axe optique ; par axe transversal, on entend l'axe perpendiculaire à l'axe optique dans un plan de support des sources lumineuses ;
• au moins deux réflecteurs sont configurés de manière à présenter des focales différentes les unes des autres ;
• un premier des deux réflecteurs présente une focale plus petite que celle du deuxième des deux réflecteurs, et ce deuxième des deux réflecteurs est disposé entre le premier des deux réflecteurs et le cache ;
• le module lumineux comporte trois réflecteurs avec un premier des trois réflecteurs qui présente une focale plus grande que celle des deux autres réflecteurs, et ce premier des trois réflecteurs est disposé entre les deux autres réflecteurs ;
• au moins une source lumineuse comporte un ou plusieurs moyens d'émission dont l'intensité d'émission peut être modifiée, la source lumineuse étant pilotée en fonction de la position du cache par variation de l'intensité d'émission des rayons émis par la source ;
• au moins une source lumineuse comporte une pluralité d'éléments émissifs, adressables sélectivement, la source lumineuse étant pilotée en fonction de la position du cache par allumage et/ou extinction de ces éléments émissifs ;
• chacune des sources lumineuses est pilotée de manière à modifier l'intensité lumineuse émise par cette source en fonction de la position du cache, dans un sens de réduction de l'intensité ou dans un sens d'augmentation de l'intensité lorsque le cache passe d'une position donnée à l'autre, deux sources lumineuses étant pilotées dans des sens opposés lors du passage du cache d'une position donnée à une autre ;
• le cache est mobile en rotation, autour d'un axe transversal ; par axe transversal, on entend comme précédemment l'axe perpendiculaire à l'axe optique dans un plan de support des sources lumineuses ;
• le cache comporte deux parois, configurées pour prendre une position décalée l'une de l'autre le long de l'axe optique lorsque le cache est dans une première position d'obturation partielle des rayons ; dans cette première position d'obturation, le bord d'extrémité libre d'une paroi est situé au voisinage du plan foyer rouge de la lentille et le bord d'extrémité libre de l'autre paroi est situé au voisinage du plan foyer bleu de la lentille ;
• le module lumineux comporte un organe de refroidissement sur lequel sont fixés, directement ou indirectement, les sources lumineuses et le dispositif de déviation, ledit organe de refroidissement étant disposé à l'opposé du dispositif de déviation par rapport aux sources ; on pourra privilégier un agencement particulier du module dans lequel les composants sont empilés verticalement, avec l'organe de refroidissement au-dessous ;

According to various features of the invention, taken alone or in combination, provision may be made for:

• the light sources are driven independently of one another according to the position of the cache;
• the light module comprises an ignition control module of the light sources configured to receive information from a cache control module;
• the cache control module is configured to instruct a cache drive mechanism to position said cache in a first partial shutter position, wherein part of the rays emitted by the light sources is blocked by the cache , or in a second disengagement position, in which none, or at most a small amount opposite the part of the rays blocked by the cover in the first position, rays emitted by the light sources is blocked by the cache ; by small or small amounts of rays relative to the first part, it is understood that at most 10% of the amount of rays corresponding to the first part is blocked by the cover in the second disengagement position;
• the deflection device comprises a plurality of reflectors respectively associated with one of the light sources;
• the deflection device comprises two reflectors arranged one after the other along the optical axis;
• the deflection device comprises at least two reflectors arranged one beside the other, transversely to the optical axis; transverse axis means the axis perpendicular to the optical axis in a support plane of the light sources;
• at least two reflectors are configured to have different focal lengths;
• a first of the two reflectors has a smaller focal length than the second of the two reflectors, and the second of the two reflectors is disposed between the first of the two reflectors and the cache;
• the light module comprises three reflectors with a first of the three reflectors which has a greater focal length than the other two reflectors, and this first of the three reflectors is arranged between the two other reflectors;
• at least one light source comprises one or more transmission means whose emission intensity can be modified, the light source being controlled according to the position of the cache by varying the emission intensity of the rays emitted by the source;
• at least one light source comprises a plurality of emissive elements, selectively addressable, the light source being controlled according to the position of the cache by ignition and / or extinction of these emissive elements;
• each of the light sources is controlled so as to modify the light intensity emitted by this source as a function of the position of the cache, in a direction of reduction of the intensity or in a direction of increase of the intensity when the cache passes from one given position to the other, two light sources being driven in opposite directions during the passage of the cache from one given position to another;
• the cover is movable in rotation about a transverse axis; transverse axis means, as before, the axis perpendicular to the optical axis in a support plane of the light sources;
• the cover has two walls, configured to take a position offset from each other along the optical axis when the cover is in a first position of partial closure of the spokes; in this first closed position, the free end edge of a wall is located in the vicinity of the plane red focus of the lens and the free end edge of the other wall is located near the blue focus plane of the lens;
• the light module comprises a cooling member on which are fixed, directly or indirectly, the light sources and the deflection device, said cooling member being disposed opposite the deflection device relative to the sources; it may be preferred a particular arrangement of the module in which the components are stacked vertically, with the cooling member below;

The invention also relates to a motor vehicle headlamp comprising a light module as just described above.

The invention furthermore relates to a lighting method of a motor vehicle, in which a first non-glare lighting function is performed, by projection of a cut-off beam, and a second long-range lighting function, by projecting a second unbroken beam, the passage from a cut-off beam to an unbroken beam being notably implemented by tilting a mask across the rays emitted by light sources, during which the pilot light intensity emitted by at least a first and a second light source according to the beam that is to be projected, the first light source being driven to emit at a higher intensity than the second light source when it is desired to produce a beam uninterrupted, while the first light source is driven to emit at a lower intensity than the second light source when it is desired to be a beam with cut.

It can be provided that the first light source is configured to emit rays spreading over the width of the beam emitted by the module, and that the second light source is configured to emit concentrated rays in the center of the beam emitted by the module, and the lighting method may in this case be characterized in that the control of the first light source in reduction of light intensity is simultaneous with the increase in the intensity of the emission of the second light source, and simultaneous with the tilting of the cache in a position of partial shutter radii for the realization of a cut-off beam.

As a variant, a control of the first light source in increase of light intensity can be simultaneous with the reduction of intensity of the emission of the second light source, and simultaneous with the tilting of the cover in a release position allowing passage to the all the rays for the realization of an unbroken beam.

• la figure 1 est une vue schématique d'un module lumineux selon un premier mode de réalisation de l'invention, illustrant les trajets de certains rayons émis par les sources de manière à représenter un premier mode de fonctionnement pour l'émission d'un faisceau de type « feux de croisement » ;
• la figure 2 est une vue schématique du module lumineux de la figure 1, illustrant les trajets de certains rayons émis par les sources de manière à représenter un deuxième mode de fonctionnement pour l'émission d'un faisceau de type « feux de route » ;
• la figure 3 est une vue schématique d'un module lumineux selon un deuxième mode de réalisation de l'invention, illustrant plus particulièrement l'effet d'un cache à double paroi agencé sur l'un des foyers d'un des réflecteurs associés à l'une des sources lumineuses ;
• la figure 4 est une illustration en perspective d'un exemple de réalisation d'un tel cache à double paroi ;
• la figure 5 est une vue schématique de dessus d'un module lumineux selon un premier mode de réalisation de l'invention, illustrant les trajets de certains rayons émis par les sources de manière à représenter un premier mode de fonctionnement pour l'émission d'un faisceau de type « feux de route » ; et
• les figures 6 et 7 sont des représentations schématiques illustrant respectivement un faisceau de type « feux de route » et un faisceau de type « feux de croisement » tel qu'ils peuvent être projetés sur une paroi à distance du module lumineux et sur lesquelles on a rendu compte du pilotage des sources lumineuses correspondant à l'émission des rayons formant ces différents faisceaux.

Other characteristics, details and advantages of the present invention will emerge more clearly on reading the detailed description given below by way of indication, in relation to the different exemplary embodiments of the invention illustrated in the following figures:

• the figure 1 is a schematic view of a light module according to a first embodiment of the invention, illustrating the paths of certain rays emitted by the sources so as to represent a first mode of operation for the emission of a beam of type " headlights ";
• the figure 2 is a schematic view of the light module of the figure 1 , illustrating the paths of certain rays emitted by the sources so as to represent a second mode of operation for the emission of a "high beam"beam;
• the figure 3 is a schematic view of a light module according to a second embodiment of the invention, illustrating more particularly the effect of a double wall cover arranged on one of the focal points of one of the reflectors associated with one light sources;
• the figure 4 is a perspective illustration of an exemplary embodiment of such a double-walled cover;
• the figure 5 is a schematic view from above of a light module according to a first embodiment of the invention, illustrating the paths of certain rays emitted by the sources so as to represent a first mode of operation for the emission of a beam of the "high beam"type; and
• the Figures 6 and 7 are schematic representations respectively illustrating a beam of the "high beam" type and a beam of the "low beam" type such that they can be projected onto a wall remote from the light module and on which the steering of the lights has been reported. light sources corresponding to the emission of the rays forming these different beams.

A light module 1 according to the invention is intended to be implanted in a motor vehicle headlamp. This module comprises at least two light sources 2, 4, respectively associated with an optical deflection device 6, 8 of the light rays that they are capable of emitting, as well as an optics for shaping the deviated rays. optical shaping being common to each of the optical deflection devices 6, 8. It is understood that the emitted rays are thus deflected out of the light module 1 and participate in the formation of a lighting beam and / or signaling . According to the invention, the light module is configured to be able to emit, as a function of the control of the light sources in particular, at least two types of light beams among which a beam of the "low beam" type and a beam of the "high beam" type ", Which differ from each other as well by the shape, respectively with or without interruption at the level of the horizon line, as by the luminous intensity, namely respectively a homogeneous intensity on the whole beam, or approximately homogeneous in that the intensity can decrease between the center of the beam and the edges of the beam when one is in beam type "low beam", or a maximum intensity in the center and more diffuse on the sides . In addition, the maximum intensity of the "high beam" beam is greater than the maximum intensity of the "low beam" beam, in particular about twice as high.

The shaping optics 10 has, in the illustrated example, the shape of a convergent lens, defining an optical axis 11 on which are arranged each of the light sources 2, 4. It is understood that the position of the light sources may vary slightly without departing from the context of the invention, these sources may be positioned slightly below or slightly above the optical axis.

The light module further comprises a cover 12, arranged between the optical deflection devices 6, 8 and the shaping optics 10, this cover 12 being movable so as to take at least two distinct positions, and in particular two extreme positions. among which a first position of partial occlusion of the rays, visible on the figures 1 and 3 , and a second release position, visible on the figure 2 .

The light module 1 further comprises one or more control or control modules 14, 16 respectively configured to control the actuation of the light sources 2, 4 and / or the luminous flux emitted by these sources and / or the position of the cover 12 .

According to the invention, the light sources 2, 4 are controlled, as well in ignition as in intensity or luminous flux emitted, as a function of the position of the cover 12, and the light module 1 comprises a control module 14 of the operation of the lights. light sources configured to receive information from a separate control module 16 dedicated to controlling the position of the cache. The two control and control modules 14, 16 comprise communication means configured to enable the exchange of information, at least in the direction from the control module 16 to the control module 14. Figures 1 and 2 there is illustrated a wired connection between the two modules but it will be understood that the communication means could consist of radiocommunication means, wireless.

We will describe later, in particular by referring to Figures 6 and 7 , how the light sources are driven according to the position of the cache. In particular, it can be provided that at least one light source comprises one or more transmission means whose emission intensity can be modified, the light source being controlled according to the position of the cache by varying the intensity of the light. emission of the rays emitted by the source.

Each of the light sources can thus be controlled so as to modify the luminous flux emitted by this source as a function of the position of the mask, in a direction of reduction of the luminous flux or in a direction of increase of the luminous flux when the mask goes from one given position to another. It will be understood from the following that the two light sources can in particular be driven in opposite directions during the passage of the cache from one position to another. Furthermore, it is possible to maintain a light source that emits in all cases a higher luminous flux than that emitted by the other light source, since according to the invention, the sources are controlled by increasing and reducing the luminous flux at each change of position of the cache.

Each optical deflection device 6, 8 comprises according to the invention a reflector 7, 9, these reflectors being respectively associated with one of the light sources 2, 4, each of the sources and the optical deflection device being made integral with a support 18 on which is also reported a heat exchange device 20.

The light sources are in particular arranged on a first face 21 of the support 18, and in particular on an upper face facing the substantially elliptical reflectors. The heat exchange device 20 may be fixed on the support, on a face opposite this first face 21, or may be made in one piece with this support. In the illustrated examples, the components are arranged vertically so that the light sources 2, 4 and the reflectors 7, 9 are arranged on an upper face of the support 18, the heat exchange device 20 being arranged under the light sources.

In the embodiments illustrated on the Figures 1 to 4 two light sources and two reflectors are provided, each reflector being secured to the support 18 to be in a specific position relative to the corresponding light source.

In particular, each reflector has a shell shape with a reflective inner surface 22 elliptical or substantially elliptical, so that each reflector has two focal points, with the light source corresponding which is positioned at the first focus of the reflector. The light source emits the majority of its light energy towards the reflecting inner surface and, because of its arrangement in the vicinity of the first focus of the reflector, the emitted rays are deflected towards the second focus of the reflector. According to the elliptical or substantially elliptical character of the zone of the reflecting internal surface 22 on which the rays emitted by the light source impact, the rays are deviated to pass precisely to the second focus, or to move to greater or lesser spreading distance. around the second focus, and thereby form a spot capable of forming the appropriate beam after projection by the shaping optics.

The reflectors are configured and positioned relative to each other so that the second foci are arranged in the vicinity of one another, and advantageously combined.

For each set formed of a light source and a reflector, in a vertical section containing the optical axis, the light source 2, 4 is turned towards the reflector 7, 9 being disposed on the one hand substantially on the optical axis 11 defined by the shaping optics, here a lens, and secondly at the first focus f17, f19 corresponding reflector 7, 9. Moreover, the second focus f2 of this reflector is substantially coincident with the focus object of the lens, so that the rays emitted from the first focus f17, f19 and deflected so as to pass through the second focus are able to exit the lens, towards the outside of the device, parallel to the optical axis .

The two reflectors 7, 9 are arranged one behind the other along the optical axis 11.

A first reflector 7 forms a first optical deflection device 6, associated with a first light source 2, arranged on the optical axis 11, and a second reflector 9 forms a second optical deflection device 8, associated with a second light source 4 , also arranged on the optical axis 11 so as to be found on this optical axis between the first light source and the lens forming forming optics 10.

The second reflector 9 is open in its rear part, that is to say the part opposite to the shaping optics, so as to form a continuity with the first reflector, so that the rays deviated by the surface reflective of the first reflector towards the shaping optics are not affected by the presence of the second reflector.

According to the invention, the two reflectors 7, 9 are configured so as to have different focal lengths from each other. In the case illustrated in the figures, the first reflector has a focal length F1 smaller than the focal length F2 of the second reflector, the second of the two reflectors being, as previously specified, disposed between the first reflector and the cover.

The short focal length of the first reflector 7 allows the projection of a wide light beam, preferred for the creation of a beam extending over the entire road scene, as desired for a beam type "low beam". Moreover, as it is visible on the figure 4 , the shape of the inner reflective surface of the first reflector 7 is calculated to spread the deviated rays on either side of the second focus on a first spreading distance d1 (visible on the figure 5 ).

For this purpose, it is possible to define in particular the reflecting surface with an elliptical shape in a band defined around the optical axis and a substantially elliptical shape on the edges of this surface.

The long focal length of the second reflector 9 allows the opposite projection of a concentrated light beam around the optical axis, which allows to form a point of higher concentration in the beam, as desired for a beam of type "high beam". Moreover, as it is visible on the figure 4 the shape of the reflective inner surface of the second reflector 9 is calculated to at least spread the deviated rays, so that the spreading of these rays on either side of the second focus is on a second lower spreading distance. at the first spreading distance d1, and here minimal so that it is merged with the second focus and all the rays deviated by the second reflector (shown with a double arrow on the figure 5 ) come out of the shaping optics 10 parallel to the optical axis. This results in an infinite image concentrated around the optical axis, which ensures the beam spot, that is to say the point of maximum luminous flux centered on the road end to be illuminated.

In contrast, because of the spreading distance d1, some of the rays deviated by the first reflector (represented with a simple arrow on the figure 5 ) come out of the shaping optics 10 diverging with respect to the optical axis. The result is an infinite beam spread.

We understand that figure 5 illustrates in plan view how the arrangement of the reflectors, offset and with a different focal distance from one another, makes it possible to devote the assembly formed by the first light source and the first reflector to the realization of the beam width, while the assembly formed by the second light source and the second reflector provides the beam spot.

As it is visible on the Figures 1 to 4 , the cover 12 is arranged in the light module 1 so that a free end edge of this cover is disposed in the vicinity of the second focus of the reflectors.

In the first embodiment illustrated on the Figures 1 and 2 , the cover 12 is rotatable about a transverse axis, that is to say an axis perpendicular to the optical axis of the light module, and consists of a plate whose end edge 24 is configured to be in the vicinity of the second foci of the optical deflection device. The control in position of the cover 12 allows, by instruction of the associated control module 16 to a drive mechanism, here an actuator not shown and associated with the cache, to pass as described above a first closed position partial ray, in which a first part of the rays emitted by the light sources is blocked by the cache ( figure 1 ), at a second release position, in which none, or at most a small amount opposite the first part of the rays blocked by the cover in the first position, rays emitted by the light sources is blocked by the hidden ( figure 2 ).

The cover 12 may comprise a free end edge 24 whose profile has an inclined portion forming a substantially central step, so that, as it is visible on the figure 7 illustrating the projected cut-off beam when the cover 12 is in the partial blocking position of the spokes, the beam has such a step in its upper part which makes it possible to illuminate one side of the road scene further without risking dazzling the vehicles arriving on the other side of the road scene.

It is understood that the principle of the cache is the following: the rays R1 which are not emitted precisely at the first focus f17, f19, or even the rays which are spread on either side of the second focus f2 because of the shape of the non-perfectly elliptical reflective inner surface are blocked when it intersects the optical axis upstream of the second focus f2, it being understood that these rays, if they were not blocked, would be directed upwards out of the lens since cutting the optical axis upstream of the object focus of the lens.

Due to the use of the cache and its possible tilting, it is possible to realize in the same light module both a first non-glare lighting function, by projection of a cut-off beam, and a second lighting function to long range, by projecting a second beam without interruption.

We will now describe the operation of the light module and in particular the control of the light sources according to the position of the cache.

When, as is most often the case during the running of the invention, it is desired to make a cut-off beam for a first non-glare lighting function, the control module 14 sends an instruction relating to an operation to high charge of the first light source 2, associated with the first reflector 7 with short focal length, and an instruction relating to a low load operation of the second light source 4, associated with the second reflector 9 at large focal length. In order to facilitate reading, it is shown schematically on the figure 1 , illustrating the embodiment of a first non-glare lighting function, a first light source emitting at full load a number of rays, here three, larger than the number of rays, here a, emitted at low load by the second light source.

According to the invention, it is advantageous to provide the different light sources with emissive elements configured to emit at different powers, so that the first light source comprises emitting elements capable of emitting at full load light rays capable of forming a light beam having an intensity of 50 lux maximum, and so that the second light source comprises emissive elements capable of emitting at full load light rays capable of forming a light beam having an intensity of between 50 lux and 100 lux.

In the case of a first non-glare lighting function, the aim is, by way of example, of lighting the road scene with an intensity of the order of 50 lux maximum, having a beam spread homogeneously, of so that the luminous flux emitted by the second light source is reduced so as to reduce it to a value close to that of the luminous flux emitted by the first light source.

It should be noted that the "lux" intensity values are obtained for beam projection on a plane perpendicular to the optical axis at 25 m, the measurement being made on this plane. Moreover, the values of 50 lux and 100 lux mentioned above are relative to light emission values of a projector, it being understood that a difference of up to 15% can be recorded between the emission values of a projector. a projector and that of a light module housed in a projector.

As illustrated on the figure 1 , to obtain a first non-glare lighting function, the cover 12 is controlled to be in the position of partial blocking of the rays, so as to block the rays likely to be projected beyond the line horizon and therefore likely to dazzle other users. As it is visible on the figure 7 the result is a beam, referred to as code beam 30, with a cutoff edge 32 of a profile equivalent to the end edge 24 of the cover 12, and comprising a first wide zone 34 formed by the shaping of the emitted rays. by the first light source and deviated by the first short-focal reflector and a second zone 35 at the center of the beam in which the luminous flux is slightly greater than in the first wide zone, due to the superposition of the rays emitted by each of the light sources.

When the user issues a command to switch from the first non-glare lighting function to the second lighting function, or when the elements on board the vehicle detect favorable conditions to switch to this second lighting function, c that is to say, when a need for a strong light is felt without dazzling another user of the road, the passage of a beam cutoff to a beam without cut is implemented by moving the cache from the partial shutter position to the release position. In the case illustrated, the cache is pivoted, by instruction from the control module 16, to no longer be across the rays emitted by light sources, as is visible on the figure 2 .

According to the invention, the information relating to the displacement of the cover is taken into account in order to trigger an operating instruction of one or more light sources by the control module 14. It may in particular be provided that the control module 16 is configured to communicate the information relating to the movement of the cache directly to the control module.

Simultaneously, or in the continuity of the movement of the cover, the control module 14 generates and transmits at least one operating instruction to each of the two light sources, the operating instruction can consist of an on / off command or a Instruction regarding the intensity of operation.

In a particular embodiment of the invention, the two light sources are continuously lit that it is desired to implement the first or second lighting function, and the light intensity emitted by each of the sources is piloted. depending on the beam that is to be projected.

In particular, the control module 14 sends an instruction relating to a low-load operation of the first light source 2 and an instruction relating to full load operation of the second light source.

It is understood that in a particular embodiment of the invention, the control in reducing the luminous flux of one of the light sources and increasing the luminous flux of the other light source is performed simultaneously with the change of position of the cache.

Thus, in a first case, the piloting of the first light source for the increase of its luminous flux can be simultaneous with the reduction of the luminous flux of the second light source, and simultaneously with the tilting of the cache in a partial shut-off position. rays for producing a cut-off beam.

And in a second case, the piloting of the first light source for the reduction of its luminous flux can be simultaneous with the increase in the luminous flux of the second light source, and simultaneously with the tilting of the cover in a release position allowing passage to the totality of the rays for the realization of an unbroken beam.

When switching from the first non-glare lighting function of the "low beam" type to the second lighting function of the "high beam" type, the operating instructions correspond to a request to reduce the luminous flux resulting from the emission of rays by the first light source and a request to increase the luminous flux resulting from the emission of rays by the second light source.

As it is visible on the figure 6 as a result, a beam, said road beam 38, without cutoff, and having a first wide zone 40, formed by the shaping of the rays emitted by the first light source and deflected by the first short-throw reflector and a second zone. 42 in the center of the beam, with the second zone 42 in which the luminous flux is greater than in the first wide zone 40.

Subsequently, when identified a situation requiring ironing in a code-type lighting mode, that is to say during a passage from the second lighting function, of the "high beam" type, to the first non-glare lighting function, of the type 'Passing beam' means the operating instructions corresponding to a request for an increase in the luminous flux resulting from the emission of rays by the first light source and a request to reduce the luminous flux resulting from the emission of rays by the second light source.

According to the invention, the operating instructions of the light sources for managing the increase or reduction of the luminous flux can be defined so that the luminous flux in each of the zones is increasing according to whether we consider the first wide zone 40 of the light. beam 38, the first wide zone 34 of the code beam 30, the second central zone 36 of the code beam 30 and the second central zone 42 of the road beam 38. It has been illustrated in order to account for this operation dimensioning possibility. sources according to the projected beam, corresponding zones on the Figures 6 and 7 with filling lines of the zones all the more tight as the luminous flux is important.

The shape and the arrangement of the reflectors forming optical deflection device 6, 8 may vary and may in particular consist of at least two reflectors arranged one in the vicinity of the other, transversely to the optical axis. For example, it will be possible to envisage having an optical deflection assembly comprising three reflectors with a first of the three reflectors which has a greater focal length than that of the other two reflectors, and in that this first of the three reflectors is arranged between the two other reflectors.

A second embodiment of the invention will now be described, with particular reference to the illustration of the figure 3 , which differs from the first embodiment in that the cover 112 has two walls.

Such a double-walled cover is used in particular to treat chromatic problems at the cut in the case of a formation of a beam type "low beam". Indeed, the reflectors consist of achromatic systems, in which the light rays have the same independently of their wavelengths. On the other hand, the shaping optics constituted by a thick convex plane lens as illustrated is highly chromatic, that is to say that the path of the light rays depends on their wavelengths. The position of the object focus of the lens along the optical axis 11, common to the reflectors and the lens, will depend on the wavelength considered. In particular, we can consider, for simplicity, the blue and red wavelengths of the visible light and define so, for the lens, a blue focus Fb and a red focus Fr.

When setting up the system, a draw adjustment makes it possible to position the lens so that its blue focus Fb, or its red focus Fr, coincides with the second focus of the reflectors. At infinity, or at a great distance with respect to the dimensions of the projector, the image of the physical limit of a simple cache, as illustrated on the Figures 1 and 2 , could be iridescent of a color depending on the draw setting of the lens, and in particular red, conversely blue, if it is the blue focus Fb, conversely the focus Fr, which is confused with the second focus of the reflectors.

The color sensitivity is here reduced by the use of the double-walled cover 112 arranged so that the walls 44, 46 are offset along the optical axis. In the first configuration position, the end edges 124 of the walls of the cover are located in the vicinity of the optical axis with the edge of the first wall 44 which is located in a plane adjacent to the red focus plane Fr of the lens and the edge of the second wall 46 which is located in a plane close to the blue focus plane Fb of the lens. It is understood that this arrangement could be achieved, in an equivalent manner, by the implementation of two successive independent caches.

Here, the two walls are formed from a single metal piece cut, stamped and folded substantially V-shaped or U-shaped upwardly concave, so that the cover has a base 48 at which is formed l 'rotation axis. The walls are configured to assume a position offset from each other along the optical axis when the cover is in a first position shutter radii, as visible on the figure 3 .

Preferably, the second wall 46 has an opaque transverse strip 50 defining the upper end edge 124 and, beneath this strip, a zone 52 transparent to the light rays which extends on either side of the optical axis.

The cutouts of the end edges of the walls 44, 46 of the cover 112 are substantially the same, as visible on the figure 4 . An inclined edge connects a horizontal upper part and a horizontal lower part of the upper end edge to one another, and it can be provided that the point of intersection of the horizontal upper part and the inclined edge for the wall 46 associated with the blue focus plane Fb is positioned on the optical axis.

The edge cut-outs give superimposed images which make it possible to obtain a neutral cutoff of the light beam, devoid of iridescence.

It is understood that for the second wall, only the upper part or transverse band 50, corresponding to the cut, contributes to the elimination of the risk of iridescence of the beam, so that the presence of the transparent zone 52 does not alter the character achromatic of the whole. On the other hand, this transparent zone 52 allows rays to participate in the formation of the beam. This results in a significant improvement in the photometric performance of the projector, and obtaining points of higher concentration near the cut.

The foregoing description clearly explains how the invention makes it possible to achieve the objectives it has set itself, and in particular to propose a light module that makes it possible to carry out two distinct lighting functions, in particular with a quality of homogeneity of the beam. of "low beam", an optimization of the use of the emitting elements forming each of the light sources associated with the realization of one or the other of the beams, and if necessary the obtaining of a beam cut not iridescent.

Of course, various modifications may be made by the person skilled in the art to the light module for a motor vehicle which has just been described by way of non-limiting example, provided that the transmission operating characteristics are conditioned. a light source depending on the position of a cache also used to cut a portion of the beam when it is desired to obtain a non-glare beam. It would be possible, instead of controlling the emitting elements forming the light source or sources, to control the luminous flux by the control of additional filter (s) for example, the arrangement of which would participate as a function of the position cache to increase or decrease the luminous flux emitted by the sources.

In any event, the invention can not be limited to the embodiment specifically described in this document, and extends in particular to all equivalent means and any technically operating combination of these means.

Claims (16)

Light module (1) for a motor vehicle comprising at least two light sources (2, 4), optical deflection devices (6, 8) for the light rays emitted by the light sources (2, 4), a shaping optics (10) deflected spokes, and a cover (12, 112) arranged between the optical deflection devices and the shaping optics and adapted to take at least two distinct positions, characterized in that the light sources (2, 4) are controlled according to the position of the cover (12, 112). Light module according to Claim 1, characterized in that the light sources (2, 4) are controlled independently of each other as a function of the position of the cover (12, 112). Light module according to claim 1 or 2, characterized in that it comprises a control module (14) for the ignition of the light sources (2, 4) configured to receive information from a control module (16). ) of the cache (12, 112). Light module according to the preceding claim, characterized in that the control module (16) of the cover (12, 112) is configured to instruct a drive mechanism of the cover so as to position said cover in a first position, in which a first part of the rays emitted by the light sources is blocked by the cover, or in a second position, in which none, or a small quantity with respect to said first part, of the rays emitted by the light sources is blocked by Cache. Light module according to one of the preceding claims, characterized in that the optical deflection devices comprise reflectors (7, 9) respectively associated with one of the light sources (2, 4). Light module according to the preceding claim, characterized in that at least two reflectors (7, 9) are arranged one after the other along the optical axis (11) of the shaping optics (10). ). Light module according to one of claims 5 or 6, characterized in that at least two reflectors (7, 9) are configured to have different focal lengths (F1, F2). Light module according to claims 6 and 7, characterized in that a first (7) of the two reflectors has a focal length (F1) smaller than the focal length (F2) of the second (9) of the two reflectors, and that second (9) of the two reflectors is disposed between the first (7) of the two reflectors and the cover (12, 112). Light module according to one of the preceding claims, characterized in that at least one light source (2, 4) comprises one or more transmission means whose emission intensity can be modified, the light source being controlled by depending on the position of the cache by varying the emission intensity of the rays emitted by the source. Light module according to one of the preceding claims, characterized in that at least one light source (2, 4) comprises a plurality of selectively addressable emitting elements, the light source being controlled according to the position of the cover (12). 112) by igniting and / or extinguishing these emissive elements. Light module according to one of the preceding claims, characterized in that each of the light sources (2, 4) is controlled so as to modify the light intensity emitted by this source as a function of the position of the cover, in a direction of reduction. intensity or in a direction of increase of intensity when the cover (12, 112) passes from one given position to the other, two light sources being driven in opposite directions during the passage of the cache of a given position to a other. Light module according to one of the preceding claims, characterized in that the cover (112) comprises two walls (44, 46), configured to assume a position offset from each other along the optical axis when the cache is in a first position shutter radii. Motor vehicle headlamp comprising a light module (1) according to one of the preceding claims. A method of illuminating a motor vehicle, in which a first non-glare lighting function is performed by projecting a cut-off beam and a second long-range lighting function by projecting a second beam without interruption, the passage from a cut-off beam to an unbroken beam being implemented in particular by tilting a mask across the rays emitted by light sources, during which the light intensity emitted by at least a first and a second light source depending on the beam to be projected, the first light source being driven to emit at a higher intensity than the second light source when it is desired to produce a non-cut beam, while the first The light source is driven to emit at a lower intensity than the second light source when it is desired to make a beam with a cutoff. Lighting method according to the preceding claim, wherein the first light source is configured to emit rays spread over the width of the beam emitted by the module, and wherein the second light source is configured to emit concentric rays in the center the beam emitted by the module, characterized in that the piloting of the first light source in reduction of light intensity is simultaneous with the increase in intensity of the emission of the second light source, and simultaneously with the tilting of the cache in a position of partially occluding the rays for producing a cut-off beam. An illumination method according to claim 16 or 17, wherein the first light source is configured to emit radii spread over the beam width emitted by the module, and wherein the second light source is configured to emit concentrated beams in the center of the beam emitted by the module, characterized in that the piloting of the first light source in increase of light intensity is simultaneous with the intensity reduction of the emission of the second light source, and simultaneously with the tilting of the cache in a release position allowing passage to all the rays for producing an unbroken beam.

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