FR3075924A1 - BRIGHT BEAM SCANNING LIGHT MODULE, IN PARTICULAR FOR A MOTOR VEHICLE, EQUIPPED WITH A TWO-LENS FOCUSING SYSTEM, AND A LIGHTING DEVICE FOR A MOTOR VEHICLE - Google Patents

Abstract

The invention relates to a light beam scanning light module (1), especially for a motor vehicle headlamp, comprising a light source (3) configured to generate a light beam (4) which has a slow axis and a fast axis. , a wavelength conversion element (7) having a conversion surface, and scanning means (5) arranged to scan the conversion surface with the light beam (4), the light module (1) comprising in addition a focussing system (2) arranged to focus the light beam (4) on the conversion element (7), the focusing system (2) comprising a first convergent lens (8) configured to converge the light beam (4) according to the fast and slow axes so as to adapt the width of the light beam (4) along the fast axis to the dimensions of the scanning means (5), the focusing system comprising a second lens (9) substantially cylindrical configured to converge the light beam along the slow axis only so that the second lens (9) adjusts the width of the light beam (4) along the slow axis to the dimensions of the scanning means (5) without changing the light beam (4) along the fast axis.

Description

Light module with light beam scanning, in particular for a motor vehicle, provided with a focusing system with two lenses, and light device for a motor vehicle comprising such a light module.

The present invention relates to a light beam scanning light module, in particular for a motor vehicle, provided with a light beam collimation system. The invention also relates to a motor vehicle headlight comprising such a light module.

Motor vehicle headlamps are provided with one or more light modules arranged in a housing closed by a window so as to obtain one or more lighting and / or signaling beams at the exit of the headlamp. In a simplified manner, a light module of the housing comprises in particular a light source, for example one (or more) light-emitting diode (s), which emits a light beam, an optical system for projecting the lighting beam comprising a or several lenses and, where appropriate an optical element, for example a reflector, for orienting the light rays coming from the light sources, in order to form the light beam leaving the optical module. The situation is the same for the rear lights.

In the automotive world, automakers and OEMs are continuously seeking to improve vehicle performance and safety through technical innovations. Thus, new technical elements are incorporated into these vehicles which provide specific advantages.

For example, in the case of light modules for vehicle light devices, there are laser diodes which can advantageously replace the light-emitting diodes to produce the light beam which will be used to form the lighting and / or output signaling beam.

However, the usual laser beams are of a color which does not correspond to the regulatory colors of such headlights or rear lights. The light module then includes a wavelength conversion element, which has a conversion surface. The conversion element receives the light beam from the laser source and re-emits it, for example in white light, towards the projection optical system. Thus, the laser beam is not used directly to form the lighting and / or signaling beam, but it is first projected on the photoluminescent wavelength conversion element, which is for example of the type phosphorescent and / or fluorescent.

To illuminate a wide area of the conversion element with the light beam from the laser source, scanning means are required. The scanning by the beam is carried out from one edge to the other of the zone of the conversion element, and preferably at a sufficiently high frequency so that the human eye does not perceive the movement and sees a continuous lighting of the light beam produced by the light module. The scanning amplitude defines the displacement of the light beam in space and therefore the size of the lighting area on the conversion element.

The known scanning means are for example MEMS type elements (for “Micro-Electro-Mechanical-Systems” in English or electromechanical microsystems), comprising one or more micro-mirrors which reflect the laser beam on the area. These micro-mirrors are for example driven by at least one rotary movement about an axis which generates the scanning of the area in a first direction. A second micro-mirror or other rotary movement of the first mirror around a second axis perpendicular to the first axis allows scanning in two directions.

The dimensions of these elements generate layout constraints for each of them in the light module. In fact, the distance between the scanning means and the conversion element defines the size of the area scanned by the light beam, since the scanning amplitude is dependent on the configuration of the scanning means. We are also looking to obtain a specific laser width size on the conversion element, and which we call target or "spot". Thus, it is the spot that is scanned over the area of the conversion element.

In addition, for reasons of efficiency, it is desirable to illuminate the surface of the micro-mirror in a substantially complete manner, while preventing the beam from overflowing beyond the edges of the micro-mirror, under penalty of burning the other elements constituting the means of sweeping and losing energy. Consequently, the light beam of the source must be calibrated to adapt its width to the dimensions of the micro-mirrors. There are, for example, laser sources which produce a light beam 27pm wide, and scanning means, the micromirrors of which are approximately 270pm wide. Thus, in this case, it is necessary to obtain a magnification of the width of the beam substantially equal to 10 times when it reaches the micro-mirror.

For this, one can use a light beam focusing system, comprising for example a converging lens to modify the dimensions of the light beam and adapt them to those of the micro-mirror (s).

However, some laser beams which are very useful in industrial production, for example of the multimode type, are not "Gaussian", that is to say that they generate light which is less coherent than a single mode laser. These laser beams have a width which is not homogeneous in all directions when the beam leaves the light source. The beam has a substantially rectangular shape with a first axis along which the beam is narrow and a second axis along which the beam is wider. In addition, along the first axis, which is said to be "fast", the beam diverges more strongly than along the second axis, which is said to be "slow". In other words, the behavior of the laser beam in the near field and in the far field is not the same in both directions. Thus, the beam width is greater in the direction of the slow axis than in the direction of the fast axis at the light source.

Consequently, it is not possible to correctly focus such a laser light beam in order to adapt it both to the dimensions of the micromirror (s) and to obtain a spot of the desired size on the conversion element.

The object of the invention is to remedy this drawback, and aims to provide a light module provided with a focusing system capable of modifying the width of the light beam so as to adapt it to the dimensions of the micro-mirror (s) to both along the major axis and along the minor axis.

For this, the invention relates to a light beam scanning lighting, in particular for a motor vehicle, comprising a light source configured to generate a light beam which has a slow axis and a fast axis, a conversion element wavelength having a conversion surface, and scanning means arranged to scan the conversion surface with the beam, the light module further comprising a focusing system arranged to focus the light beam on the conversion element, the focusing system comprising a first converging lens configured to converge the light beam along the fast and slow axes so as to adapt the width of the light beam along the fast axis to the dimensions of the scanning means, the focusing system comprising a second substantially cylindrical lens configured to converge the light beam according to the slow axis only so that the second lens adapts the width of the light beam along the slow axis to the dimensions of the scanning means without modifying the light beam along the fast axis.

A conversion element comprises at least one luminescent material designed to absorb at least a part of at least one excitation light emitted by a light source and to convert at least a part of said absorbed excitation light into light of emission having a wavelength different from that of excitation light. Preferably the lumlinescent material used is chosen from the following compounds: Y3A150i2: Ce3 + (YAG), (Sr, Ba) 2SiO4: Eu2 +, Cax (Si, AI) i2 (O, N) i6: Eu2 +.

Thus, the first converging lens converges the entire light beam towards the scanning means, that is to say both along the fast axis and the slow axis. It is calibrated to adapt the beam width along the rapid axis only. However, the beam along the slow axis is also modified. The second substantially cylindrical lens allows the beam width to be further modified along the slow axis so that it converges more. As the lens is cylindrical, it only has an effect on the beam along the slow axis, and not on the fast axis of the beam which is already properly focused by the first lens.

In addition, the use of two lenses brings an advantage to simplify the manufacture of the focusing system compared to a focusing system which would have only one lens combining the effects of the two lenses. Indeed, it suffices to manufacture on the one hand a converging lens and on the other hand a cylindrical lens, while a single lens would be complex to produce in large quantities. In addition, this facilitates adjustments for configurations of light modules provided with different light sources and scanning means.

According to different embodiments of the invention, which can be taken together or separately: - the first lens is a substantially aspherical lens, - the first lens is arranged upstream of the second lens on the optical path of the light beam between the source of light and the scanning means, - the first lens is a thin lens,

“Thin lens” is understood to mean that the thickness of the lens remains small compared to the radii of curvature of its faces as well as to the difference of these radii. - the second lens comprises a convergent output diopter along the slow axis and having a convex curvature, - the output diopter is substantially cylindrical with an axis substantially parallel to the rapid axis, - the second lens comprises a convergent output diopter along the slow axis, - the output diopter has a convex curvature having a substantially cylindrical portion whose axis is substantially parallel to the rapid axis, - the second lens comprises an input diopter diverging along the slow axis, - the input diopter has a concave curvature having a substantially cylindrical portion whose axis is substantially parallel to the rapid axis, - the input diopter is configured to reduce, or even substantially cancel the effect produced by the first lens on the light beam along the slow axis, - the second lens is a thick lens,

The term “thick lens” is understood to mean that the thickness of the lens is greater than or equal to the largest dimension of the input and output diopters. - the first and second lenses are arranged coaxially to the optical axis of the light beam, - the scanning means are provided with one or two mobile micro-mirrors configured to scan the transmission surface with the light beam in a first direction and / or a second direction substantially perpendicular to the first direction, - the light source comprises at least one laser diode, the light beam generated being a laser beam, - the conversion element comprises a phosphor material, - the phosphor material is a fluorescent and / or phosphorescent material, - the phosphor material is present over substantially the entire surface of the conversion element. The invention also relates to a motor vehicle light device comprising such a light module. It can further comprise a projection system. The projection system comprises at least one lens and / or at least one mirror and / or at least one light guide. The invention will be better understood in the light of the following description which is given for information only and which is not intended to limit it, accompanied by the accompanying drawings among which: - Figure 1 illustrates schematically , a side sectional view of a light module according to an embodiment of the invention, - Figure 2 schematically illustrates, a top sectional view of part of the light module along the minor axis, - FIG. 3 schematically illustrates a sectional view from above of part of the light module along the major axis, FIG. 4 illustrates schematically a headlight of a motor vehicle comprising a light module according to the invention.

As illustrated in FIG. 1, the light module 1, in particular used in a light device, in a rear light and / or in a device for interior lighting of a motor vehicle, comprises a source 3 of coherent light capable of generating a beam light 4 which has an axis of propagation along (Oz), a slow axis along (Ox) and a fast axis along (Oy). The three axes are perpendicular two by two as shown by the reference (Oxyz). The slow axis and the fast axis define the width of the light beam in the plane (Oxy) of the light source, the propagation axis being collinear with the light beam 4. The beam has a width of rectangular shape, which is more smaller along the fast axis than that of the beam along the slow axis. The source 3 is here a laser diode which generates a laser beam whose light waves have substantially the same wavelength value, for example 448nm to have a blue color.

The device 1 also comprises a wavelength conversion element 7 having a photoluminescent conversion surface configured to transform the wavelength of the light beam, for example by spreading the distribution of the light waves over wavelength values corresponding to different colors. Thus, a beam in another color, for example a white color, is obtained from the initial light beam 4, thanks to the conversion element. The white light beam serves for example as a lighting beam in a motor vehicle headlamp.

The light module 1 also comprises scanning means 5 of the surface of the conversion element 7 by the light beam 4. The scanning means 5 are MEMS type elements (for “Micro-Electro-Mechanical-Systems >> in English or electromechanical microsystems), which here comprise two micro-mirrors 6, 7. The first micro-mirror 6 is arranged in the axis of propagation of the beam. The first micro-mirror reflects the light beam 4 towards the second micro-mirror 7 which reflects it towards the conversion surface of the conversion element 7. These micro-mirrors are driven in a rotary movement around an axis which generates the scanning of the surface of the conversion element 7 in a direction each. The scanning by the beam 4 is carried out from one edge to the other of a chosen zone on the conversion surface at a sufficiently large frequency, for example 200 Hz, so that the human eye does not perceive the movement and sees continuous illumination of the lighting beam generated by the conversion element.

The light module 1 further comprises a focusing system 2 disposed between the light source 3 and the scanning means 5 for focusing the light beam 4, on the one hand on the scanning means so as to cover a large part of the microphones -mirrors avoiding overflowing beyond their surface, and in order to obtain a desired spot size on the conversion surface of the conversion element 7.

The scanning means 5, the conversion element 7 and the focusing system 2 are arranged so that the light beam 4 generated by the light source first meets the scanning means 5, then the conversion element 7 .

According to the invention, the focusing system 2 comprises a first 8 and a second 9 lens. The first lens 8 is here arranged upstream of the second lens 9 on the optical path of the light beam between the light source and the scanning means 5. In other words, the light beam 4 generated by the light source first passes through the first lens, then the second lens, before reaching the scanning means. The first and second lenses are arranged coaxially to the optical axis of the light beam along the axis Oz, so that the light beam 4 passes through the lenses 8, 9 being substantially centered.

As shown in Figures 2 and 3, the first lens 8 is configured to converge the light beam 4 both along the fast and slow axes. It is in particular provided for adapting the width of the light beam 4 along the fast axis to the dimensions of the scanning means 5, here at the first mirror 6, as well as to the desired spot size on the conversion element. To this end, the first lens 8 is a substantially convergent thin convergent lens, and biconvex here. The expression "substantially spherical" means that the input diopter 10 has a curvature having a portion of a sphere or close to a sphere. Such lenses are commonly called "aspherical lenses". The first lens 8 has a sufficiently short focal length so that the magnification of the light beam 4 along the fast axis on the scanning means 5 is sufficient. Indeed, as the first lens 8 is close to the light source 3, the value of the focal length must be small.

In addition, the first lens 8, in addition to adapting the width of the beam 4 along the fast axis, also modifies the width of the beam along the slow axis. However, the focal length of the first lens is too short to obtain a sufficiently small spot size on the conversion element. To correct the width of the beam along the slow axis also and to make the beam converge, the focusing system 2 comprises a second lens 9 configured to converge the light beam 4 only along the slow axis. Thus, as shown in FIG. 2, the second lens 9 adapts the width of the light beam 4 along the slow axis to the dimensions of the micro-mirror 6 of the scanning means. It also makes it possible to obtain a specific spot size on the conversion surface along the slow axis.

For this purpose, the second lens 9 is substantially cylindrical and comprises a converging output diopter 13 comprising a convex curvature having a substantially cylindrical portion whose axis is substantially parallel to the rapid axis. The term convex means that the curvature of the output diopter 13 is curved towards the outside of the lens, and the expression “substantially cylindrical” means that the diopter has a curvature having at least one portion of a cylinder or close to a portion cylinder. Here it is a cylinder in the mathematical sense, that is to say that the cross section of the cylinder is not necessarily circular. Thus, only the width of the light beam 4 along the slow axis is modified. The focal length of the output diopter is chosen to be greater than that of the first lens in order to modify the width of the light beam along the slow axis so as to have a desired spot size in this direction. In addition, the width along the fast axis is not changed by the input diopter of the second lens because the output diopter 13 is substantially flat along the slow axis, as shown in Figure 3. Thus, the output diopter 13 of the second lens 9 is provided with only one curvature.

The second lens 9 preferably comprises an input diopter 12 diverging along the slow axis and having a concave curvature. The term concave means that the curvature is recessed towards the inside of the lens. The input diopter 12 has a curvature having a substantially cylindrical portion whose axis is substantially parallel to the rapid axis. The divergence of the input diopter 12 is preferably chosen so as to greatly reduce the convergent effect of the first lens 8 along the slow axis only, or even to cancel it completely. The input diopter 12 thus makes it possible to form a virtual image of the source 3 in the plane of the slow axis.

The second lens 9 is further configured to have no effect on the beam 4 along the rapid axis, so as not to modify the size of the spot which is already correctly adapted by the first lens 8. For this purpose the diopter output 13 is substantially flat along the rapid axis, so that the light beam 4 is not changed in this direction at the output of the second lens. Thus, the input diopter 12 of the second lens 9 is provided with only one curvature.

In addition, the second lens 9 is a thick lens so that the input diopter 12 and the output diopter 13 are sufficiently distant. The term "thick" means that it is not a conventional thin lens. The thickness of the lens defines the distance between the output diopter 13 and the input diopter 12, so that the virtual image of the source 3 is placed relative to the focal length of the output diopter 13 to obtain a correct adjustment of the width of the light beam along the slow axis.

Thanks to the invention, such a focusing system provided with a first thin convergent lens 8 and a thick cylindrical lens 8 makes it possible to obtain a spot size in accordance with what is desired, both according to the 'slow axis and along the fast axis.

FIG. 4 mounts a headlight 15 of a motor vehicle provided with a light module 1 as described above. The light device 15, here a projector, also includes a projection system 16 configured to direct the light beam outside the projector. The projection system 16 is for example provided with a projection lens placed downstream of the light module to transmit a beam intended to illuminate the road.

Claims (14)

1. Light module (1) with light beam scanning, in particular for a motor vehicle, comprising a light source (3) configured to generate a light beam (4) which has a slow axis and a fast axis, a conversion element (7) of wavelength having a conversion surface, and scanning means (5) arranged to scan the conversion surface with the light beam (4), the light module (1) further comprising a system of focusing (2) arranged to focus the light beam (4) on the conversion element (7), the focusing system (2) comprising a first converging lens (8) configured to converge the light beam (4) according to the fast and slow axes so as to adapt the width of the light beam (4) along the fast axis to the dimensions of the scanning means (5), the focusing system comprising a second substantially cylindrical lens (9) configured to make converge the light beam along the slow axis only so that the second lens (9) adapts the width of the light beam (4) along the slow axis to the dimensions of the scanning means (5) without modifying the light beam ( 4) along the rapid axis. 2. Light module according to claim 1, wherein the first lens (8) is a substantially spherical lens. 3. Light module according to claim 1 or 2, wherein the first lens (8) is arranged upstream of the second lens (9) on the optical path of the light beam (4) between the light source (3) and the scanning means (5). 4. Light module according to any one of the preceding claims, wherein the first lens (8) is a thin lens. 5. Light module according to any one of the preceding claims, in which the second lens (9) comprises an exit diopter (13) converging along the slow axis, the exit diopter (13) having a convex curvature having a portion substantially cylindrical, the axis of which is substantially parallel to the rapid axis. 6. Light module according to any one of the preceding claims, in which the second lens (9) comprises an input diopter (12) diverging along the slow axis, the input diopter (12) having a concave curvature having a substantially cylindrical portion whose axis is substantially parallel to the rapid axis. 7. Light module according to claim 6, wherein the input diopter (12) is configured to substantially cancel the effect produced by the first lens (8) on the light beam (4) along the slow axis. 8. Light module according to any one of the preceding claims, in which the second lens (9) is a thick lens. 9. Light module according to any one of the preceding claims, in which the first (8) and the second (9) lens are arranged coaxially with the optical axis of the light beam (4). 10. Light module according to any one of the preceding claims, characterized in that the scanning means (4) are provided with one or two mobile micro-mirrors (6, 7) configured to scan the conversion surface with the beam. luminous (4) in a first direction and / or a second direction substantially perpendicular to the first direction. 11. Light module according to any one of the preceding claims, characterized in that the light source (3) comprises at least one laser diode, the light beam (4) generated being a laser beam. 12. Light module according to any one of the preceding claims, characterized in that the conversion element (7) comprises a phosphorescent material. 13. Motor vehicle light device comprising a light module (1) with light beam scanning according to any one of the preceding claims. 14. Lighting device according to the preceding claim, further comprising a projection system (16).