FR3123415A1 - Light module comprising a light-absorbing element - Google Patents

Abstract

The invention relates to a motor vehicle light module (1) comprising: a light sub-module (10) comprising a primary light source (11) capable of emitting light rays; a primary collector (12) with a reflecting surface (120) configured to collect and reflect at least a part of the light rays emitted by the primary light source into a primary reflected light beam (FR1) along an optical axis (A1) of the sub-module;a primary projection optic (13) configured to project the primary reflected light beam (R1) into a primary projected light beam (P1) by imaging a part of the reflective surface located behind the primary light source. According to the invention, the light module comprises a light-absorbing element (15) arranged between the primary collector and the primary projection optic. FIG. 1

Description

Light module comprising a light-absorbing element

The present invention belongs to the field of lighting, in particular lighting for motor vehicles. The invention relates in particular to a light module intended to be mounted in a motor vehicle headlamp.

State of the art

In the field of automotive lighting, it is generally known light devices mounted in a headlight of the vehicle to project light beams performing photometric lighting and / or signaling functions. In particular, the light beam performing the lighting photometric function can be a cut-off lighting beam. The latter is obtained by using a bending light device. Such a light device conventionally comprises a collector with a reflective surface of revolution with an elliptical profile, in the shape of a cap in a half-space delimited by a horizontal plane. An essentially point-like light source, of the light-emitting diode type, is located at a first focal point of the reflecting surface and illuminates in the half-space in the direction of said surface. The rays are thus reflected in a convergent manner towards a second focal point of the reflecting surface. Another, generally flat, reflective surface with a cut-off edge at the second focal point provides upward reflection of rays which do not pass precisely through the second focal point, these rays then being refracted by a thick lens towards the bottom of the beam lighting. This reflective surface is commonly referred to as a "bender" in that it "bends" up the projection lens the rays that would otherwise form a top portion of the illumination beam. Such a light device has the disadvantage of requiring significant precision in the positioning of the folder and the cutting edge. Also, the projection lens must be a thick lens due to its short focal length, which increases its weight and complicates its production, such as shrinkage defects in particular. In addition, the collector has a certain height and, therefore, a certain overall height.

The published patent document WO 2020/025171 A1 discloses a light module comprising a sub-module with a collector with a reflective surface collecting and reflecting the light rays emitted by a light source into a light beam, similar to a bender light module. The light module also includes projection optics, such as a lens, specifically configured to project the light beam in question forming an image of the reflective surface of the collector. To this end, the projection optics has a focal zone on the reflecting surface, for example at a rear edge of the latter so as to correctly image said edge and form a sharp cut in the projected light beam.

However, some rays emitted by the light source and not reflected by the reflective surface of the collector can reach the projection optics by bouncing off the walls of the box in which the lighting unit is housed. In the same way, a minority of the light rays reflected by the reflective surface are deflected by the walls of the casing on reaching them and arrive on the projection optics along an unplanned path.

These light rays are unwanted rays and can degrade the quality of the projected light beam by causing spots or light portions to appear that do not comply with automotive lighting regulations.

In order to reduce the disturbing light rays originating from the return by the walls of the casing, a mask is placed on the internal face of these walls. The mask is made of plastic and has relief patterns to prevent these annoying rays from reaching the projection optics. Indeed, when these light rays reach patterns in relief, they are diffused by them and are dispersed into several much less luminous rays so that their path is not directed towards the projection optics and so that even if part of these scattered rays arrive on the projection optics, their image is of very low luminous intensity and imperceptible on the photometric grid.

However, this type of mask remains perfectible, in particular, in terms of effectiveness in blocking rays following an unwanted path. Indeed, it may happen that the light rays are not dispersed by the relief patterns but on the contrary they undergo multiple reflection by the mask and still reach the projection optics. In addition, due to the relief patterns, this type of mask has a certain thickness, and requires a case large enough to fit into it. Thus, the placement of the mask with relief patterns imposes a size limit of the case below which the use of the mask is no longer possible. The mask will therefore stand in the way of reducing the size of the case. However, a reduced-size case makes the light module more compact, which is an increasingly frequent request from automobile manufacturers. Finally, the manufacture of the mask with the patterns in relief is sometimes complicated and expensive because of the complex geometry of the patterns. Indeed, certain particular shapes of the patterns require additional machining steps and/or a structural modification of these shapes in order to guarantee a good demolding of the mask.

The present invention improves the situation.

An objective of the invention is to reduce the number of parasitic rays in the light module while making it possible to obtain a compact structure of the light module.

• un sous-module lumineux comprenant :
  • une source lumineuse primaire apte à émettre des rayons lumineux ;
  • un collecteur primaire avec une surface réfléchissante configurée pour collecter et réfléchir au moins une partie des rayons lumineux émis par la source lumineuse primaire en un faisceau lumineux réfléchi primaire suivant un axe optique du sous-module ;
  • une optique de projection primaire configuré pour projeter au moins la majorité du faisceau lumineux réfléchi primaire en un faisceau lumineux projeté primaire en imageant une partie de la surface réfléchissante située, suivant une direction générale de propagation du faisceau lumineux réfléchi suivant l’axe optique, à l’arrière de la source lumineuse primaire ; et

To this end, a first aspect of the invention relates to a vehicle light module comprising:

• a light sub-module comprising:
  • a primary light source capable of emitting light rays;
  • a primary collector with a reflective surface configured to collect and reflect at least a portion of the light rays emitted by the primary light source into a primary reflected light beam along an optical axis of the sub-module;
  • a primary projection optic configured to project at least the majority of the primary reflected light beam into a primary projected light beam by imaging a portion of the reflective surface located, along a general direction of propagation of the reflected light beam along the optical axis, at the rear of the primary light source; and

According to the invention, the light module comprises a light-absorbing element which is arranged between the primary collector and the primary projection optic.

Thus, the light-absorbing element intercepts light rays that may interfere with the overall projected light beam. Once these disturbing light rays are intercepted, they are retained by the absorbing element. The absorbing element, as its name suggests, absorbs disturbing light rays and limits, or even completely prevents, the formation of stray rays by reflecting disturbing light rays on its surface. These rays no longer continue to propagate in the light sub-module. There are therefore no more residual annoying light rays, also called parasitic light rays, which can reach the projection optics. Therefore, the light-absorbing element improves the effectiveness of blocking stray light rays, resulting in good quality of the overall projected light beam.

According to one embodiment of the invention, the light-absorbing element comprises a mask coated with a light-absorbing layer which is arranged so as to receive direct light rays emitted forwards by the primary light source and not -reflected by the primary reflecting surface, and/or part of the light rays reflected by the primary reflecting surface. In this embodiment, the mask may have a flat surface on which a light-absorbing layer is applied. The mask thus configured is simple to manufacture and economical. In addition, the deposition of the absorbent layer on the mask is facilitated.

• Une couche de peinture noire (par exemple Aeroglaze™ de Lord Corporation, DeSoto™) ou d'anodisations (par exemple Martin Black™, Enhanced Martin Black™, ou Infrablack™ de Martin Marietta Corporation, etc.) ; ou
• Un revêtement inorganique de la société Acktar (Nano black™, Magic black™, Vacuum black™, Fractal black™ et Ultra black™), ce revêtement étant fabriqué à l'aide de la technologie de dépôt sous vide et se caractérisent par une très faible réflectance, donc une capacité d’absorption de lumière élevée ;
• un matériau super-noir (appelé Vantablack™), développé par la société Surrey NanoSystems, qui absorbe 99,96% de la lumière de surface. Vantablack™ est produit par un procédé de croissance de nanotubes de carbone (NTC) à basse température. Lorsque la lumière atteigne la couche de NTC, au lieu de rebondir, elle est piégée entre les tubes avant de devenir finalement de la chaleur.

By way of example, the light-absorbing layer can be:

• A coat of black paint (eg Aeroglaze™ from Lord Corporation, DeSoto™) or anodizations (eg Martin Black™, Enhanced Martin Black™, or Infrablack™ from Martin Marietta Corporation, etc.); Where
• An inorganic coating from the company Acktar (Nano black™, Magic black™, Vacuum black™, Fractal black™ and Ultra black™), this coating being manufactured using vacuum deposition technology and characterized by a very low reflectance, therefore a high light absorption capacity;
• a super-black material (called Vantablack™), developed by Surrey NanoSystems, which absorbs 99.96% of surface light. Vantablack™ is produced by a low temperature carbon nanotube (CNT) growth process. When light hits the CNT layer, instead of bouncing it is trapped between the tubes before eventually becoming heat.

According to one embodiment of the invention, the light-absorbing element is a mask made of a light-absorbing material and arranged so as to receive direct light rays emitted forwards by the primary and non-reflected light source. by the primary reflecting surface, and/or part of the light rays reflected by the primary reflecting surface. In this embodiment, the step of depositing the light-absorbing layer is dispensed with, which makes it possible to shorten the manufacturing time of the mask while preserving the same blocking efficiency of the mask.

By way of example, the light-absorbing material may be in black aluminum, in particular anodized. It may be in a material considered to be a good thermal conductor.

According to one embodiment of the invention, the mask has a thickness of between 0.3 mm and 3 mm, preferably between 0.5 mm and 1 mm. The mask proposed by the invention is thinner than the mask comprising relief patterns of the state of the art. The mask proposed by the invention is therefore suitable for a reduced-size box, in particular at low height.

According to one embodiment of the invention, the light-absorbing layer or the light-absorbing material has a light absorption coefficient greater than or equal to 90%, preferably greater than or equal to 95%. The light absorption coefficient is a parameter which is inversely proportional to the reflectance. The higher the light absorption coefficient, the lower the reflectance, and vice versa. In the example of anodized aluminum, the latter has a very low reflectance, with a value of about 2%. Anodized aluminum therefore has a very high light absorption coefficient which allows said material excellent absorption of incident light rays.

According to one embodiment of the invention, the light-absorbing layer or the light-absorbing material is dark in color, in particular black in color.

According to one embodiment of the invention, the primary projection optic has a focal zone located on the reflective surface of the primary collector, behind the primary light source. Advantageously, the focal zone can be located at a rear edge of said reflective surface. In general, this focal zone can be a focal point, also called a focal point, or can be a focal line, also called a line of focal points.

• une source lumineuse secondaire ;
• un collecteur secondaire avec une surface réfléchissante configurée pour collecter et pour réfléchir au moins une partie des rayons lumineux émis par ladite source lumineuse secondaire en un faisceau lumineux réfléchi secondaire suivant un axe optique du deuxième sous-module;
• une optique de projection secondaire configurée pour projeter au moins la majorité du faisceau lumineux réfléchi secondaire en un faisceau lumineux projeté secondaire en imageant une partie de la surface réfléchissante située, suivant une direction générale de propagation du faisceau lumineux réfléchi suivant ledit axe optique, à l’arrière de la source lumineuse secondaire.

According to one embodiment of the invention, the sub-module is a first sub-module; the light absorbing element being a first light absorbing element. The light module further comprises a second light sub-module comprising:

• a secondary light source;
• a secondary collector with a reflecting surface configured to collect and to reflect at least a part of the light rays emitted by said secondary light source into a secondary reflected light beam along an optical axis of the second sub-module;
• secondary projection optics configured to project at least the majority of the secondary reflected light beam into a secondary projected light beam by imaging a portion of the reflective surface located, along a general direction of propagation of the reflected light beam along said optical axis, at the rear of the secondary light source.

In this embodiment, a partition is placed between the first sub-module and the second sub-module; said partition being made of a light-absorbing material or being coated with a light-absorbing layer.

Thus, the light module can generate a first light beam with the first light sub-module and a second light beam with the second light sub-module.

By way of example, the first light beam can perform a first photometric function. The second light beam can perform, alone or in combination with the first light beam, a second photometric function. The first photometric function can be a code-type lighting function, also referred to as “low beam”. The second photometric function can be a road-type lighting function, also referred to as “high beam” in English.

The partition separating the first light sub-module from the second light sub-module makes it possible to bring them closer while preventing the light rays from one of the two sub-modules reaching the other of the two sub-modules. In addition, the partition is structured in such a way as to be able to absorb light rays that reach it, which further reduces the risk of stray light rays appearing.

According to one embodiment of the invention, the second sub-module comprises a second light-absorbing element disposed between the secondary collector and the secondary projection optics, said second light-absorbing element being of the same nature as the first absorbing element the light. In other words, the second light sub-module is also equipped with a light-absorbing element to prevent the formation of stray light rays and thus to ensure a good quality of the second light beam.

By way of example, the light module further comprises a housing comprising at least one wall. The latter delimits a chamber in which the first light sub-module and/or the second light sub-module is arranged. In an exemplary embodiment, the first light-absorbing element and/or the second light-absorbing element can be arranged on an internal face of the wall of the casing.

Another object of the invention relates to a vehicle headlamp, in particular a motor vehicle headlamp, comprising a light module according to the invention.

Here, the term "vehicle" means any type of vehicle such as a motor vehicle, a moped, a motorcycle, a storage robot in a warehouse, or any other machine capable of carrying at least one passenger or intended for the transport of people. or objects.

Other characteristics and advantages of the invention will appear on examination of the detailed description below, and of the appended drawings in which:

is a schematic representation, in sectional view, of a light module according to an example embodiment according to the invention;

is a schematic representation, seen from above, of the light module of the .

In this document, unless otherwise indicated, the terms "upstream" and "downstream" refer to the direction of propagation of the light beam in the object to which it refers and also to the direction of emission of light outside of said object.

Moreover, everything called "rear" is on the upstream side while everything called "front" is on the downstream side.

The terms "horizontal", "vertical" or "transverse", "lower", "upper", "top", "bottom", "side" are defined in relation to the orientation of the light module or a part forming part of the light module according to the invention in which it is intended to be mounted in the vehicle. In particular, in this application, the term "vertical" refers to an orientation perpendicular to the horizon while the term "horizontal" refers to an orientation parallel to the horizon.

In Figures 1 and 2, there is shown an orthogonal marker associated with the lighting device 30. This marker is composed of three axes X, Y and Z being called, here, respectively longitudinal axis X, transverse axis Y and vertical axis Z .

Claims (10)

Vehicle light module (1) comprising:

• a light sub-module (10) comprising
  • a primary light source (11) capable of emitting light rays;
  • a primary collector (12) with a reflective surface (120) configured to collect and reflect at least a portion of the light rays emitted by the primary light source into a primary reflected light beam (F _R1 ) along an optical axis (A1) of the sub -module;
  • a primary projection optic (13) configured to project at least the majority of the primary reflected light beam (R ₁ ) into a primary projected light beam (P ₁ ) by imaging a part of the reflecting surface located, along a general direction of propagation (X) of the light beam reflected along the optical axis, at the rear of the primary light source;

characterized in that the light module comprises a light absorbing element (15) disposed between the primary collector and the primary projection optic. Light module (1) according to claim 1, wherein said light absorbing element (15) comprises a mask (16) coated with a light absorbing layer (151) which is arranged to collect direct light rays emitted towards the front by the primary light source and not reflected by the primary reflecting surface, and/or part of the light rays reflected by the primary reflecting surface. Luminous module (1) according to Claim 1, in which the light-absorbing element (15) is a mask (16) made of a light-absorbing material and arranged so as to collect direct light rays emitted forwards by the primary light source and not reflected by the primary reflecting surface, and/or part of the light rays reflected by the primary reflecting surface. Light module (1) according to Claim 3 or according to Claim 4, in which the mask (16) has a thickness of between 0.3 mm and 3 mm, preferably between 0.5 mm and 1 mm. Light module (1) according to one of the preceding claims, in which the light-absorbing layer (151) or the light-absorbing material has a light absorption coefficient greater than or equal to 90%, preferably greater than or equal to 95%. Light module (1) according to one of the preceding claims, in which the light-absorbing layer (151) or the light-absorbing material is dark in color, in particular black in color. Light module (1) according to one of the preceding claims, in which the primary projection optics (13) has a focal zone (F) located on the reflecting surface (120) of the primary collector (12), at the rear of the primary light source (11). Light module (1) according to one of the preceding claims, in which:

• the sub-module is a first sub-module (10); the light absorbing element (15) being a first light absorbing element (15);
• the light module (1) further comprises a second light sub-module (20) comprising:
  • a secondary light source (21);
  • a secondary collector (22) with a reflective surface configured to collect and reflect at least part of the light rays emitted by said secondary light source into a secondary reflected light beam along an optical axis (A2) of the second sub-module;
  • secondary projection optics (23) configured to project at least the majority of the secondary reflected light beam into a secondary projected light beam by imaging a portion of the reflecting surface located, along a general direction of propagation (X) of the next reflected light beam said optical axis, at the rear of the secondary light source;
• a partition (30) is disposed between the first sub-module (10) and the second sub-module (20); said partition being made of a light-absorbing material or being coated with a light-absorbing layer.

Luminous module (1) according to the preceding claim, comprising a second light-absorbing element arranged between the secondary collector (22) and the secondary projection optic (23), in which the said second light-absorbing element is of the same nature as the first light-absorbing element. Vehicle headlamp comprising a light module (1) according to one of the preceding claims.