FR3062894A1 - LUMINOUS DEVICE OF LASER SCANNING VEHICLE - Google Patents

Abstract

The present invention relates to a vehicle light device comprising: - a wavelength converter (2), - one or more scanning devices for scanning the converter by means of a laser beam (R1, R2), so that the converter emits secondary light radiation (R') of a wavelength different from that of this laser beam, the converter comprising at least a first portion (21) and a second portion (22) having different structures and being arranged so as to be able to be scanned by the laser beam or beams, the second structure having a resistance to irradiation by laser beam greater than that of the first structure.

Description

© Publication number: 3,062,894 (to be used only for reproduction orders) (© National registration number: 17 51175 ® FRENCH REPUBLIC

NATIONAL INSTITUTE OF INDUSTRIAL PROPERTY

COURBEVOIE © IntCI ⁸ : F 21 V14 / 00 (2017.01), F 21 S 41/16

A1 PATENT APPLICATION

©) Date of filing: 14.02.17. (© Applicant (s): VALEO VISION Joint-stock company (© Priority: simplified - FR. @ Inventor (s): MOREL XAVIER and EL IDRISSI HAFID. (43) Date of public availability of the request: 17.08.18 Bulletin 18/33. ©) List of documents cited in the report preliminary research: Refer to end of present booklet (© References to other national documents (73) Holder (s): VALEO VISION Joint stock company related: folded. ©) Extension request (s): (© Agent (s): VALEO VISION Limited company.

LIGHT DEVICE OF LASER SCANNING VEHICLE.

FR 3 062 894 - A1

The present invention relates to a vehicle light device comprising:

- a wavelength converter (2),

- one or more scanning devices to scan the converter by means of a laser beam (R1, R2), so that the converter emits secondary light radiation (R ') with a wavelength different from that of this laser beam, the converter comprising at least a first portion (21) and a second portion (22) having different structures and being arranged so that they can be scanned by the laser beam (s), the second structure having a resistance to irradiation by laser beam greater than that of the first structure.

LASER SCANNING VEHICLE LIGHT DEVICE

The present invention relates to the field of vehicle light devices, in particular light devices emitting a road lighting beam.

More particularly, the invention relates to light devices, in which the light beam is formed by a light converter of one wavelength into another wavelength swept by a laser beam.

Light devices are known, the light source of which is formed by a light converter comprising a phosphor material. This converter is scanned by a laser beam of a given wavelength converted into radiation of another given wavelength, in particular of white color, the converter thus forming the light source whose rays will form the light beam lighting.

A shaping optic collects these light rays and deflects them so as to obtain a light beam corresponding to the projection of the shape of the light source. By appropriately controlling the laser beam, it is thus possible to generate a light pattern on the surface of the converter variations having a different shape and intensity, the projection of this pattern forming the light beam with the required photometry, in particular as to its shape. and at different intensities within the light beam. The document FR2993831A1 describes a device of this type.

Thus, depending on the desired light beam, certain portions of the converter can be more irradiated, that is to say receiving a greater amount of energy by the laser beam, that is to say subject to a duration of exposure to it. higher laser beam and / or a higher laser beam intensity - than others. For example, to generate a high beam, also called long range beam, the center of the converter will be irradiated with a higher intensity compared to that applied to the edges of the converter.

It follows that certain portions may be overexposed in terms of intensity. The subsequent heating can lead to degradation of the material in the overexposed portion greater than that of the other portions. As a result, over time, the converter may lose performance. For example, the color nuances may no longer correspond from one overexposed portion to another.

The technical problem which the invention aims to solve is therefore to improve the lifetime and / or the constancy of the performance over time of a converter formed from a material converting radiation of a wavelength into radiation of another wavelength and scanned by a laser beam to produce a light beam with areas having different intensities.

To this end, a first object of the invention is a vehicle light device comprising:

a converter formed from one or more wavelength converting materials, one or more scanning devices arranged so as to be able to scan the converter by means of one or more laser rays, the converting material or materials converting the or the laser rays which sweep it or them into a secondary light radiation of a wavelength different from that of the laser beam (s), the converter comprising at least a first portion and a second portion having respectively a first and a second structures, the first portion being arranged so that it can be scanned by the laser beam of the scanning device or at least one of the laser beams of the scanning devices, the second portion being arranged so that it can be scanned by the laser beam of the scanning device or at least one of the laser beams of the scanning devices, the second structure having a resistance to irradiation by laser beam greater than that of the first structure.

By resistance to higher laser beam irradiation of a second structure compared to a first structure, it is meant that each structure has a threshold of quantity of energy transferred to the corresponding structure by laser beam irradiation, threshold beyond from which the structure degrades, the threshold of the second structure being higher than the threshold of the first structure.

Thus, the light device can be controlled so that the laser beam scans the second portion so as to further irradiate the latter so that the light intensity of the radiation coming from the second portion is greater than that of the radiation coming from the first portion, while having a degradation of the second portion limited compared to the degradation of the first portion. The performance of the radiation emitted by the converter will thus be stable over the entire converter during the lifetime of the light device. In particular, a difference in the shade of color emitted according to the portions of the converter is avoided.

The light device according to the invention can optionally include one or more of the following characteristics:

the converter material (s) are phosphors; for example, the converting material or materials comprise a binder in which phosphor elements are dispersed;

the binder of the second portion has better resistance to irradiation by the laser beam than the binder of the first portion;

the converter comprises a surface, called the total emitting surface, the scanning device being arranged to scan this total emitting surface by means of the laser beam, the second portion comprising the center of this total emitting surface; thus, the second portion is capable of generating the center of the light beam emitted by the light device according to the invention, in particular when the light device comprises a shaping optic projecting the image of the converter so as to form this light beam ;

the first and second portions respectively have a first elementary emitting surface and a second elementary emitting surface, the scanning device being arranged to scan these elementary emitting surfaces by means of the laser beam, the first and second elementary emitting surfaces being arranged in the same way side of the converter; there is thus a light pattern formed on the surface of the converter which is simple to project by means of shaping optics;

the light device comprises two scanning devices, a first scanning device being arranged to scan the converter by means of a first laser beam, a second scanning device being arranged to scan this converter by means of a second laser beam;

the laser beam of the first scanner and the laser beam of the second scanner can have the same wavelength;

the first scanning device is arranged to scan all of the portions and the second scanning device is arranged to scan only the second portion and possibly other portions separate from the first portion; this allows a simpler control of the device to form a light beam with a first area formed by the light rays coming only from the first portion and a second area formed by the light rays coming from the first and the second portion;

the scanning device (s) are arranged so as to irradiate the second portion more than the first portion; this makes it possible to emit stronger radiation from the second portion and to produce a light beam with an area having a stronger light intensity, in particular when the light device comprises a shaping optic projecting the image of the converter. so as to form this light beam;

the scanning device or devices are arranged so as to sweep the second portion more slowly than the first portion; this allows the second portion to be further irradiated;

the scanning device or devices are arranged so as to scan the second portion with a laser beam intensity greater than that with which the first portion is scanned; this allows the second portion to be further irradiated;

the scanning speed of the second scanning device is slower than the scanning speed of the first scanning device; in this case, the laser rays of the scanning devices can for example have the same intensity;

the laser beam of the first scanner has a lower intensity than that of the laser of the second scanner; in this case, the scanning devices can have the same scanning speed;

the thickness of the second portion is greater than that of the first portion; the difference in structure of the portions here corresponds at least to a variation in thickness, making the second portion more resistant to a radiation intensity and therefore capable of withstanding a higher intensity of laser radiation; the first and the second portion can be formed by the same material, in particular in one piece; this facilitates the production of the converter;

the first portion comprises a first material and the second portion comprises a second material, the second material being more resistant to irradiation than the first material; this makes it easier to design a converter with portions of different resistances for given irradiation intensities; in this case the thickness of the first portion can be identical to that of the second portion, which facilitates the integration of the converter in the light device;

the second portion comprises on the one hand a ceramic and / or glass binder, and on the other hand phosphor elements dispersed in the ceramic and / or glass binder; ceramic and glass have good resistance to irradiation;

the second portion comprises on the one hand a glass-ceramic binder, in particular Zerodur®, and on the other hand phosphor elements dispersed in the glass-ceramic binder; a vitroceromic, and in particular Zerodur ®, has in addition to good resistance to irradiation a low coefficient of thermal expansion, which facilitates positioning adjacent to and in contact with the second portion and another portion of the converter;

the first portion comprises on the one hand a silicone binder, and on the other hand phosphor elements dispersed in the silicone binder; silicone is less resistant to radiation than a ceramic, glass or a glass ceramic but is less expensive; in addition, it makes it easier to make the converter with the second portion inserted into the first portion or an intermediate portion between the first portion and the second portion;

the phosphor elements dispersed in the binder of the first portion and the phosphor elements dispersed in the binder of the second portion are identical; this makes it possible to have shades of white emitted by the portions of the converter close or even identical;

the phosphor elements dispersed in the binder of the first portion may differ from the phosphor elements dispersed in the binder of the second portion, in particular in size and density, the binder of the first portion and the binder of the second portion being adjusted so as to that the first and second portions generate identical emissions, in particular identical shades of white; for example, these binders can be chosen from materials making it possible to generate identical emissions with these phosphor elements;

the first portion is an insert inside the second portion or inside a third portion itself inserted into the second portion; this makes it possible to produce the portions separately, which can facilitate their production in particular by molding, in particular in the case where the portions are of different materials;

the converter comprises a third portion having a third structure and being arranged so that it can be scanned by said laser beam (s), the third structure having a resistance to irradiation by said laser beam (s) greater than that of the first structure and lower than that of the second structure; this makes it possible to produce a third zone in the beam or to produce a beam of which a first zone of intensity greater than a second zone of the beam is movable on either side of a central position, the first zone in central position being formed by irradiation essentially, if not only, of the first portion;

the thickness of the third portion is less than that of the second portion and / or greater than that of the first portion;

the first portion comprises a first material, the second portion comprises a second material, and the third portion comprises a third material, the third material:

o being distinct from the first material and more resistant to irradiation by the laser beam (s) than the first material, and / or o being distinct from the second material and less resistant to irradiation by the laser beam (s) than the second material .

the converter is arranged on a heat sink; improving the heat dissipation and the resistance of the converter;

the heat sink is made of metal;

the heat sink is a mirror comprising at least one reflecting face, the converter being arranged on the side of the mirror comprising the reflecting face;

the wavelength of the secondary light radiation corresponds to a white color;

the light device comprises a shaping optic arranged so as to collect the secondary light radiation and to deflect its rays so as to form a light beam and to send it out of the light device; the shaping optics can for example be arranged to project an image of the converter;

the light beam is a road lighting beam;

the converter and the shaping optics are arranged in such a way that the rays of the secondary light radiation coming from the second portion form a central part of the lighting beam; this makes it possible to produce a high intensity central part without degrading the second portion of the converter;

the converter and the shaping optics are arranged in such a way that the rays of the secondary light radiation coming from the first portion form a wide part of the lighting beam; the first portion can thus be subjected to a lower irradiation;

the converter and the shaping optics are arranged in such a way that the rays of the secondary light radiation coming from the third portion form a central zone of the light beam in a position of the light beam as it is lights up a left or right turn; this makes it possible to carry out a turn following function in which the central bet moves, independently or in solidarity with the wide portion, depending on whether the vehicle turns to the left or to the right.

The invention also relates to a vehicle comprising a light device according to the invention, in particular connected to the electrical supply of the vehicle.

The invention also relates to a method for controlling a light device according to the invention.

The method according to the invention can optionally have one or more of the following characteristics:

the method comprises a step of controlling the scanning device or devices so as to further irradiate the second portion with the laser beam, in particular by scanning it more slowly and / or by increasing the intensity of the laser beam when it scans the second portion ;

the process includes:

o a detection step if the vehicle approaches a right or left turn, o a control step of the scanning device (s) so as to further irradiate the second portion, if the vehicle is going straight ahead, o a step of driving the or scanning devices so as to further irradiate part of the second portion and the third portion with the laser beam, on one side or the other of the center of the central portion, depending on whether it was detected at step of detection that the vehicle was approaching a left or right turn.

Unless otherwise indicated, the terms "front", "rear", "lower", "upper", "side", "transverse" refer to the direction of light emission outside the corresponding light device.

According to the request, a shaping optic deflects the light rays emitted by the light source of the device and so as to confer on the beam of the light device given photometric characteristics, in particular of a beam of road lighting. The shaping optics may include a reflector, a combination of lenses, a combination of reflectors, or a combination of lenses and reflectors.

Other characteristics and advantages of the invention will appear on reading the detailed description of the following nonlimiting examples, for the understanding of which reference will be made to the appended drawings, among which:

Figure 1 is a schematic cross view of a light device according to a first embodiment of the invention;

FIG. 2 is a schematic transverse view of part of FIG. 1 with a converter according to a

first variant of the figure production r view similar to that of the 3 East a figure 2 but with i year converter according to another variant of achievement; the figure 4 East a view schematic transverse of a device according to a second embodiment of The invention; the figure 5 East a view schematic transverse of part of the figure 4, with a converter according to a first variant of production r the figure 6 East a view schematic transverse of part of the figure 4, with a converter according to a second variant of production r the figure 7 East a view schematic transverse

of a part of FIG. 4, with a converter according to a third alternative embodiment;

FIG. 8 represents a lighting beam obtained with the devices illustrated;

Figure 9 shows the converter of Figures 2 and 5, seen from below.

FIG. 1 illustrates an example of a light device according to the invention. In this example, this is a vehicle headlight 1, also called a headlight, comprising a box 6 closed by a transparent closing glass 8.

Inside the volume defined by this box 6 and this closing glass 8, various elements are placed making it possible to generate a light beam from the road F which is sent through the closing glass 8 so as to illuminate the road.

An example of such a beam is illustrated in FIG. 9. The latter illustrates a long range light, more particularly a road beam F. The latter comprises a central portion F22, comprising the highest intensity and approximately centered on the horizon H, and the vertical axis V in the extension of the longitudinal axis of the vehicle equipped with the headlamp 1. Around this central portion F22, the light beam F comprises a wider and less intense peripheral portion F21.

In this example, the central portion F21 can be moved as a function of the turns taken by the vehicle, in particular as a function of the angle at the wheel, or of information coming from an image sensor. In FIG. 9, the extreme positions of the central portion are illustrated: an extreme left position F23 for a left turn and an extreme right position F24 for a right turn. The position of the central portion can vary between these extreme positions depending on the size of the radius of curvature of the turn taken or approached.

According to the invention, the light device, in this example the projector 1 to comprise:

- a converter inside its box 6, a

projector formed from one or more wavelength converting materials,

- At least one scanning device 4 emitting a laser beam r when the projector 1 is activated, this scanning device 4 being arranged so as to be able to scan the converter 2 by means of the laser beam r.

The converting material or materials convert the laser beam which sweeps it or them into secondary light radiation R ′ with a wavelength different from that of the laser beam r.

In the example illustrated, in the case of an illumination beam F, the wavelength of the laser beam r corresponds to a blue color which the converter converts into a secondary light radiation R 'of a wavelength corresponding to a white color, here suitable for producing a lighting beam, in terms of color.

According to the invention, the converter 2 therefore forms the light source of the light device, here the

1. The laser beam r forms a primary light radiation which provides energy to this light source.

The projector 1 can include, as in this example, a shaping optic 10 arranged so as to collect the secondary light radiation R 'and to deflect its rays so as to form the light beam F and to send it out of the device luminous, through the closing glass 8.

The shaping optic 10 can be a projection lens or objective, arranged in such a way that the light beam corresponds to the projection of the shape of the light source 2.

The laser beam r is controlled so as to generate a light pattern on the surface of the converter 2 having a shape and variations in intensity of this pattern forming the r e qu i s e. The different control, the light beam projection with the photometry document FR2993831A1 describes a method making it possible to produce a light beam in this way.

In the example illustrated in FIG. 2, the laser beam r is controlled so as to scan the emitting surface of the converter 2 between its edges. The scanning interval is shown in dotted lines. Thanks to the speed of the scan, a light spot corresponding to the projection of the entire area scanned will be visible on the road. In this example, this corresponds to the entire surface of the converter located opposite the shaping optics 10.

As in this example the beam is an illumination beam F, the converter emits more intense light at its center.

In the example illustrated in FIGS. 1 and 2, this is achieved by slowing down the scanning of the laser beam r over a central portion 22 of the converter 2. Thus the converter has a first portion, here a peripheral portion 21, less irradiated than a second portion, here this central portion 22.

FIG. 9 illustrates this converter 2 in view from the side of the surface opposite the emitting surface. In FIG. 2, the converter 2 is shown in section along II in FIG. 9. It can be observed that the peripheral portion 21 and the central portion 22 have the shape of the peripheral portion F21 and of the central portion F22 of the beam F respectively, the latter being a projection of converter 2.

Thus, the central portion 22 is subjected to a stronger irradiation and presents a risk of high degradation.

According to the invention, the first portion 21, here the peripheral portion 21, and the second portion, here the central portion 22 respectively have a first structure and a second structure, the second structure having a resistance to radiation by the ray. laser r greater than that of the first structure.

In the example illustrated in FIGS. 2 and 9, this difference in structure corresponds to a different thickness.

Thus, the central portion 22 has a thickness greater than that of the peripheral portion 21. It follows that although by driving the laser more slowly over the central portion 22, and therefore as a secondary secondary intensity from to that of radiation, the port ion to the latter has a peripheral R ′ s upé ri eur 21, the degradation resistance of this central portion 22 is improved.

Furthermore, having a smaller thickness in the peripheral portion 21 saves the converter material. The latter is in this example a phosphor material, which has a significant cost.

In this example, 16 the projector 1 allows 1 a production a follow-up of turn. For that, 1 st device sweep 4 is agency for to receive a signal corresponding to a position desired to 1 a

a central part F22 of the light beam F.

This signal can in particular be transmitted by the vehicle's central computer.

According to one embodiment of the invention, converter 2 comprises a third portion, called intermediate portion 23, between the central portion 22 and the peripheral portion 21.

The light device, here the headlamp 1, may include a computer and a turn sensor. The cornering sensor can be arranged so as to detect the angle at the steering wheel or even be connected to a camera of the vehicle or of the lighting device, to determine according to the angle at the steering wheel in which position must be central to the beam, and in a manner or images placed part the consequence form which corresponding place this central part is to be scanned. The computer then controls the scanning device 4 to scan this place. The intermediate portion and the scanning device are arranged so that this location corresponds to the central portion 22 and / or to the intermediate portion 23.

It follows that during driving, there will be an area which, depending on the turns, will emit the same intensity as the central portion 22 when the vehicle is going straight ahead. On a journey, this zone, therefore the intermediate portion 23, will therefore be more irradiated than the peripheral portion 21. On the other hand, it will be less irradiated than the central portion 22, since it will only be irradiated in the event of a turn.

The intermediate portion 23 has a third structure having a resistance to irradiation by the laser beam r greater than that of the first structure and less than that of the second structure. Thus, the resistance to irradiation of the intermediate portion 23 is improved while reducing its cost in phosphor material.

In this example, this third structure corresponds to a different thickness of the converter

2. The thickness of the intermediate portion 23 is less than that of the central portion 22 and greater than that of the peripheral portion 21.

Due to the possibility of turning to the right and to the left, as can be seen in FIG. 9, the intermediate portion 23 extends to the right and to the left of the central portion in FIG. 9.

Furthermore, according to the invention, as in this example, the light device can be arranged to carry out a dynamic correction of the height of the beam F according to the roughness of the road, the accelerations, or the braking of the vehicle.

Therefore, the laser beam r will be caused to be driven to shift the central part F22 up or down.

Thus, in the same way as for cornering follow-up, if the attitude of the vehicle varies along a pitch axis, an intermediate portion 23 between the central portion 22 and the peripheral portion 21 will be caused to be irradiated, but with an offset with respect to the central portion 22 along an axis substantially perpendicular to the offset in the event of following a turn, ie from top to bottom in FIG. 9.

The coupling of turn tracking and beam height correction results in a single intermediate portion 23 capable of being scanned being distributed all around the central portion, as can be seen in FIG. 9.

The converter can be formed with portions distributed concentrically from the central portion 22, each having a given thickness, the portions being arranged in decreasing order of thickness from the central portion 22 towards the peripheral portion 21.

FIGS. 2 and 9 illustrate such a converter with, here, three portions arranged concentrically, which forms an embodiment adapted to the coupling of the turn tracking and to the correction of the beam height.

According to the invention, in particular in this example, the calibration of the height of the beam F, for example as a function of the vehicle load, or to adjust the height of the beam F when stationary, can be carried out by mechanical means providing travel:

- the shaping optics 10, and / or

- the displacement of the converter 2 in solidarity with the scanning device 4.

The light device 1 according to the invention can be simpler and not dynamic, either in height, yet ensure such correction by movement of the shaping optics 10, and / or the displacement of the converter 2 integrally with the device scanning.

ensure correction either laterally, or

For example, in such a case, as illustrated in FIG. 3, the converter 202 can have a simpler shape with only a central portion 222 and a peripheral portion 221 of different structures,

especially a portion central more thick than 1 a peripheral portion. This layout allows so to get a beam road similar to the one of 1 a f igure 9, but devoid of function feedback and of correction dynamic, the central part of the beam born

not moving with respect to the peripheral bet.

Generally, the shape of the central portion and / or of the intermediate portion will depend on the desired application for a given projector.

According to an embodiment not shown, the central portion is rectangular, and the dimensions of the rectangle are arranged so that:

- its length corresponds to the maximum angles desired to perform the cornering function,

- its width corresponds to the maximum angles desired to perform the dynamic correction function.

This rectangular arrangement can also be adapted to an embodiment not shown, in which an intermediate portion of a converter having a central portion is inscribed in the rectangle of the intermediate portion, with a peripheral portion around the intermediate portion.

If it is desired to be able to increase the intensity of the beam only in the central zone of the beam, in order for example to increase the range of the beam as a function of the speed, the arrangement illustrated in FIG. 9 is particularly suitable.

Note that in the examples illustrated, the surface of the converter 2 swept completely by the laser beam, or total emitting surface, is plane. The elementary emitting surfaces of the portions of the converter together form this total emitting surface. This makes it easier to form an image.

Therefore, when the difference in structure results from a difference in thickness between portions, this difference in thickness is produced by shoulders on the surface opposite the total emitting surface.

To improve the resistance to irradiation, as illustrated in FIG. 2, the converter 2 is placed in contact with a heat sink 12. This can have a housing of complementary shape on the opposite surface, the converter 2 being housed in this housing. .

According to the invention, the difference in structure between portions can also be a difference in materials. In such a case, the converter has portions formed of a material which is all the more resistant to irradiation as it is intended to be swept more slowly.

For example, in FIG. 3 is illustrated a variant of the converter 2 of the headlight of FIG. 1. In this variant, the converter 202 only comprises a first portion and a second portion, namely respectively a peripheral portion 221 surrounding a central portion 222.

The central portion 222 is made of a material more resistant to laser irradiation than the material constituting the peripheral portion 221.

Each of these materials comprises a binder and phosphor elements dispersed in this binder. The binder is at least partially transparent to the laser beam, so that it can better impact the phosphor elements. These latter laser radiation absorb part of the at its given wavelength, and then re-emit secondary radiation R 'with another wavelength, here a wavelength corresponding to a white color.

The phosphor elements of the first and second material can be identical.

The difference in resistance to radiation is here conferred by the binder. The binder of the central portion 222 is more resistant to laser radiation than that of the peripheral portion 221.

For example, the binder of the central portion 222 is a ceramic or glass binder, while the binder of the peripheral portion 221 is a silicone binder.

The binder of the central portion 222 can in particular be made of glass ceramic, which has a particularly strong resistance by this central radiation can be heat and

In particular, the portion by the glass ceramic

The separately laser.

form sold under the brand Zerodur ®.

The silicone binder is more cheaper than a ceramic or glass binder, and much cheaper than a glass ceramic.

In addition, by its flexibility, when using glass, silicone makes it possible to absorb the expansion of the latter more easily.

two portions have been produced here. The peripheral portion 221 comprises a through hole in which the central portion 222 is inserted.

The two portions can be of equal thickness, thus giving a constant thickness to the converter 202. This simplifies the shape of the heat sink 212 and are arranged with the converter 202, the face of the heat sink 212 in contact with the converter 202 thus being able to be plane .

According to the invention, the scanning device 4 can for example comprise a laser beam source 42 and a steerable reflector 46 in orientation and arranged to receive the laser beam emitted by the laser beam source 42. A mechanism (not shown) allows orient the controllable reflector 46 so as to scan the emitting surface of the converter 2.

As in the example illustrated, the scanning device 46 can comprise an enclosure inside which the laser beam source 42 and the controllable reflector 46 are arranged.

In the example illustrated, an optic 44 makes it possible to adjust the focus of the laser beam r.

The enclosure 40 has an output 48 of the laser beam r after reflection by the controllable reflector 46.

This outlet 48 can be closed by a glass window (not shown) which makes it possible to hermetically isolate all of the components contained in the enclosure 40.

The laser beam source 42 is in the example illustrated in FIG. 1 a single laser diode 42.

However, it is possible to use, including in a light device 1 with a single scanning device 46, two laser diodes coupled together to form a single laser beam r, as will be described below.

Note that instead of sweeping the central portion

22, 222, faster, 1 st device sweep can be controlled by increasing The intensity from the source of Ray laser 42, when 1 st laser ray r goes on 1 a central portion 22, 222 • The figure 4 illustrates a di spos it if bright 101 according to a second mode of achievement, which differs from

first embodiment in that it comprises two scanning devices 104, 105, each of them comprising two laser diodes 1 42, 1 42 'and 143, 143' inside an enclosure 140, 141.

The converter can be identical or different from those of the first embodiment. In Figures 5 to 7, three variants of converters are illustrated.

In FIG. 5, the converter 2 is identical to that of the first embodiment, and therefore has the same references.

The first scanning device 104 is disposed at the top in the housing 106 of the light device 101. The laser diodes 1 42, 1 42 'each emit an initial laser beam ri, r2, in the direction of a coupling optic 144. The latter couples the initial laser rays ri, r2, into a laser beam Ri, emitted to a controllable reflector 146.

This coupling is carried out in a known manner. In particular, the coupling optics 144 may comprise a lens and a polarization filter, in particular a quarter-wave filter, arranged to carry out this coupling. Alternatively, the coupling optics 144 may comprise an optical fiber receiving as input the two initial laser rays ri, r2, a single laser beam Ri leaving this fiber.

The second scanning device 105 is disposed at the bottom of and in the housing 106 of the light device

101. It also includes two laser diodes 143, 143 ′ inside an enclosure 141. In the same way as in the first scanning device 46, the initial laser rays r3, r4, emitted by these laser diodes 143, 143 ′ are also coupled by a coupling optic 145 into a laser beam R2 emitted towards a controllable reflector 147.

Here the light device is also a projector 101. The scanning of the converter by the two laser rays RI, R2, makes it possible to produce a secondary radiation R ′ which forms a light pattern on the surface of the converter.

The projector 101 includes an optical focusing

form 110 arranged from way to collect radiation luminous secondary R 'and to deviate his rays, of way to form a shall seal luminous F and to 1 'send out of projector 101, at t r ave r s of ice of closing 108 which closes the housing 106

143

The shaping optic 110 is for example a lens or a projection objective, arranged so that the light beam F corresponds to the projection of the shape of the light source formed by the emitting surface of the converter 2.

In this example, the light beam F is also illustrated in FIG. 8 and is identical to the first embodiment. In this example, it is therefore a road lighting beam, which can be controlled according to the turns.

The fact of using two laser diodes 142, 142 ′ and by scanning device and two scanning devices 104 and 105 makes it possible to use

143 of the laser diodes of lower power than those of the first embodiment. For example, the laser beams RI, R2, can each have a power of 10 Watts optical.

The controllable reflectors 146, 147 are, in the same way as in the first embodiment, controlled in orientation by a corresponding actuator connected to a control device (not shown), so as to scan the total emitting surface of the converter 2 However, this steering is different here.

In FIG. 5, the scanning intervals L1, L2, of the laser rays RI, R2 are illustrated by cones in

The controllable reflector 146 of the first scanning device 104 is controlled in orientation so as to scan the whole of the total emitting surface of the converter 2, namely all of the emitting surfaces of the central 22, peripheral 21 and intermediate 23 portions.

On the other hand, the controllable reflector 147 is controlled so as to scan only the emitting surface of the central portion 22 of the converter 2, and possibly the intermediate portion 23, but not

the peripheral portion 2 1. The second ray R2 laser, who East issued by the second device scanning 147, East arranged for sweep only the central portion 22, when 1st

beam is corrected to illuminate as much as possible in the center line of the vehicle, namely in the absence of a turn, which is the case in FIG. 5.

In the case of a right or left turn, the scanning interval L2 of the second laser beam R2 will be shifted to the left or to the right. The second laser beam R2 will therefore in this case irradiate part of the central portion 22 and of the intermediate portion 23.

Thus, as in the first embodiment but in a different manner, irradiation of the central portion 22 is obtained which is greater than that of the intermediate portion 23 and even more than that of the peripheral portion 21.

The converter 2 however makes it possible, as described above, to resist these different

The laser beams RI and R2 can be controlled so that the scanning speed by the second laser beam R2 is slower than that of the first laser beam. Consequently, the light intensity emitted by the central portion 22 will be all the stronger. In such a case, it is possibly possible that the two laser rays RI and R2 can be arranged to scan the converter with the same frequency. Thus, each laser beam changes scanning line at the same time; a more homogeneous beam is thus obtained.

As a variant of this second embodiment, as illustrated in FIG. 6, the converter 302 can comprise two inserts. The peripheral portion 321 comprises a central through hole inside which is housed and in contact with the edges of this hole a first insert forming the intermediate portion 323. The latter also includes a central through hole inside which is housed and in contact with the edges of this hole a second insert forming the central portion 322.

The peripheral portion 321 comprises a first material, the central portion 322 comprises a second material, the third resistant

and intermediate portion 323 comprises a material. The second material is more resistant to radiation than the third material, itself more resistant to radiation than the first material.

In the same way as for the variant of this, these materials are formed of a binder on which phosphor elements are dispersed, to convert the laser radiation. The difference in strength can also be imparted by the binder of these materials.

For example, the second material, the third material, and the first material comprise a binder respectively in Zerodur®, in a ceramic less resistant than Zerodur® but less expensive, in silicone.

In FIG. 6, the scanning interval L3 of the second laser beam R2 is also shown, when the vehicle is approaching or is in a turn.

FIG. 7 illustrates another variant of this second embodiment, in which the ways of portions the central differences 422, of structures between the intermediate 423 and peripheral 421, are a combination of the variants of FIGS. 5 and 6.

Here, the converter comprises a single piece comprising the peripheral portion 421 and the intermediate portion 423. The structure of these portions 421 and 423 differs in their thickness, the intermediate portion 423 being thicker than the peripheral portion 421. The intermediate portion 423 resists therefore better on irradiation than the peripheral portion 421.

This one-piece piece includes a through hole in the intermediate portion

423 and agency the interior of which is housed, in contact with the edges of this hole, an insert 422 of the same thickness as the intermediate portion 423 but of a material different from the one-piece 421/423. This insert forms the central portion 422.

The one-piece 421/423 is formed from a material less resistant to irradiation with laser rays than that of the insert 422. These materials can be formed from a binder inside which phosphor elements are dispersed, to convert laser radiation. The difference in strength can be imparted by the binder of these materials.

For example, the binder of the insert is made of glass or ceramic or a glass ceramic, in particular Zerodur®, and the binder of the monobloc part is made of silicone.

These different converter variants can also be used with the light device of the first embodiment.

According to the invention, the heat sink 12, 212, can comprise at least one reflecting face, the converter being arranged on the side of this reflecting face. In the embodiments where the converter has a constant thickness, this dissipator can be formed by a simple mirror.

The dissipator can possibly be arranged so as to have optical properties and to reflect certain rays emitted by the converter.

In general, the converters 2 or the blocks with portions 421/423 of different thicknesses can be produced by molding a binder containing a dispersion of phosphor elements in a mold of suitable shape.

To make converters with inserts, one can for example implement the process comprising the following steps:

- positioning of a heat sink, in particular a mirror, then

- Attachment of a pallet of glass, ceramic or glass-ceramic binder to the dissipator, by gluing and / or sintering, the binder comprising the phosphor elements, then

- application of a layer of silicone containing a dispersion of phosphor elements on the dissipator above and around the paddle,

- Smoothing of the silicone layer at the height of the pallet, preferably by scraping the surface of the latter.

A converter is thus obtained with an insert forming the central portion, with around a silicone ring adhering to this insert and forming a peripheral and / or intermediate portion.

In the variant of FIG. 7, the dissipator may have a housing whose depth corresponds to the difference in thickness between the peripheral portion and the intermediate portion. The insert 422 is positioned at the bottom of the housing, for example in the center. By its thickness, the insert protrudes from the housing.

Thus after the scraping step, the different portions 421, 422, 423 are flush with the side of the total emitting surface. The insert 422 runs right through the block 421/423.

In the variant of FIG. 6, this method is applied to produce the peripheral 321 and intermediate 323 portions. In this case, the pallet corresponds to the intermediate portion 323 and comprises a central hole, in which is adjusted before the application of the layer of silicone the insert 322 forming the central portion.

Note that in these embodiments, for the sake of clarity of the drawings, only the modules generating the driving beam have been illustrated. However, the headlamp 1 can comprise other modules, for example a module generating a passing beam, this crossing module can be produced for example in a known manner.

Claims (18)

1. Vehicle light device (1; 101) comprising: a converter (2; 202; 302; 402) formed from one or more wavelength converter materials, one or more scanning devices (4; 104, 105) arranged so as to be able to scan the converter with by means of one or more laser rays (r; RI, R2), the converting material (s) converting the laser beam (s) which sweep it (s) into secondary light radiation (R ') with a wavelength different from that of the laser beam (s) (r; RI, R2), the converter comprising at least a first portion (21; 221; 321; 421) and a second portion (22; 222; 322; 422) having respectively a first and a second structure, the first portion (21; 221; 321; 421) being arranged so that it can be scanned by the laser beam (r) of the scanning device (4) or at least one of the laser beams (RI, R2) of the scanning devices (104, 105), the second portion (22; 222; 322; 422) being arranged so that it can be scanned by the laser beam (r) of the scanning device (4) or at least one (R2) of the laser beams of the scanning devices (104 , 105), the second structure having a resistance to irradiation by laser beam greater than that of the first structure. 2. vehicle light device (101) according to claim 1, wherein the light device comprises two scanning devices, a first scanning device (104) being arranged to scan the converter (2; 302; 402) by means of a first laser beam (RI), a second scanning device (105) being arranged to scan this converter by means of a second laser beam (R2). 3. Vehicle light device (101) according to claim 2, in which the first scanning device (146) is arranged to scan all of the portions (21, 22, 23; 321, 322, 323; 421, 422, 423) and the second scanning device (147) is arranged to scan only the second portion (22; 322; 422) and possibly other separate portions (23; 323; 423) of the first portion. 4. Vehicle light device (1; 101) according to any one of the preceding claims, in which the scanning device or devices (4; 104, 105) are arranged so as to further irradiate the second portion (22; 222; 322; 422) than the first portion (21; 221; 321; 421). 5. Vehicle light device (1; 101) according to any one of the preceding claims, in which the thickness of the second portion (22; 422) is greater than that of the first portion (21; 421). 6. Vehicle light device (1; 101) according to any one of the preceding claims, in which the first portion (221; 321; 421) comprises a first material and the second portion (222; 322; 422) comprises a second material, the second material being more resistant to radiation than the first material. 7. A vehicle light device (1; 101) according to claim 6, wherein the second portion (222; 322; 422) comprises on the one hand a ceramic and / or glass binder, and on the other hand phosphor elements dispersed in the ceramic or glass binder. 8. Vehicle light device (1; 101) according to claim 6 or 7, in which the second portion (222; 322; 422) comprises on the one hand a glass-ceramic binder and on the other hand phosphor elements dispersed in the glass ceramic binder. 9. Vehicle light device (1; 101) according to any one of claims 6 to 8, in which said first portion (221; 321; 421) comprises on the one hand a silicone binder, and on the other hand phosphor elements dispersed in the silicone binder. 10. Vehicle light device (1; 101) according to any one of claims 6 to 9, in which the first portion (221; 321; 421) is an insert inside the second portion (222; 322; 422) or inside a third portion (323; 423) itself inserted into the second portion (322; 422). 11. Lighting device (1; 101) according to any one of the preceding claims, in which the converter (2; 302; 402) comprises a third portion (23; 223; 323; 423) having a third structure and being arranged to so as to be able to be scanned by said laser beam (s) (r; RI, R2), the third structure having a resistance to irradiation by said laser beam (s) greater than that of the first structure and less than that of the second structure . 12. Vehicle lighting device according to claim 11, in which the thickness of the third portion is less than that of the second portion and / or greater than that of the first portion. 13. A vehicle light device (101) according to claim 11 or claim 12, wherein the first portion (321) comprises a first material, the second portion (322) comprises a second material, and the third portion (323) comprises a third material, the third material: - being distinct from the first material and more resistant to irradiation by said laser beam (s) than the first material, and / or - Being distinct from the second material and less resistant to irradiation by said laser beam (s) than the second material. 14. Vehicle light device (1; 101) according to any one of the preceding claims, in which the converter (2; 202; 302; 402) is arranged on a heat sink (12; 212). 15. Vehicle light device (1; 101) according to any one of the preceding claims, comprising a shaping optic (10; 110) arranged so as to collect said secondary light radiation (R ') and to deflect its rays. so as to form a light beam (F) and send it out of the light device. 16. A vehicle light device (1; 101) according to claim 15, wherein said light beam (F) is a road lighting beam. 17. Vehicle light device (1; 101) according to claim 16, in which the converter (2; 202; 302; 402) and the shaping optics (10; 110) are arranged in such a way that the rays of the secondary light radiation (R ′) coming from the second portion (21; 221; 321; 421) form a central part (F22) of the lighting beam (F), and in which the converter and the focusing optics shaped are arranged so that the rays of the secondary light radiation (R ') from the first portion (21; 221; 321; 421) form a wide part of the lighting beam (F21). 18. Vehicle lighting device (1; 101) according to claim 17 when taken in combination with one of claims 11 to 13, in which the converter (2; 302; 402) and the shaping optics (10; 110) are arranged so that the rays of the secondary light radiation (R ') coming from the third portion (23; 323; 423) form a central zone (F23, F24) of the beam 5 lighting in a position of the lighting beam, depending on whether it illuminates a left or right turn. 1/4