FR3135128A1 - MULTIPLIER LIGHT MODULE - Google Patents

Abstract

MULTIPLIER LIGHT MODULE One aspect of the invention relates to a light module for a motor vehicle comprising a light source (1) of main axis X and an optical element (3), said optical element comprising: a first input surface (40 ) of light facing the light source (1), a first reflection surface (41), a second reflection surface (43), a first light output surface (44), the first reflection surface (41 ) being made up of several concave and connected faces (310) arranged circumferentially and inclined relative to the main axis and inclined with respect to the main axis X. Figure to be published with the abstract: Figure 7

Description

MULTIPLIER LIGHT MODULE TECHNICAL FIELD OF THE INVENTION

The technical field of the invention is that of light modules intended for motor vehicles.

The present invention relates in particular to a light module making it possible to multiply light sources.

TECHNOLOGICAL BACKGROUND OF THE INVENTION

Light modules used in automobiles use several light sources, most often LEDs (light-emitting diodes). In order to give a homogeneous image, the light fields emitted by the light sources must touch or overlap. Thus, the lower the depth of the module, the closer together the light sources must be, and consequently their number is increased for a given surface. Consequently, if we want to limit the number of light sources 1 used, we must place the screen 2 at a distance d ₁ sufficient so that the fields 12 of the light sources are continuously juxtaposed (cf. ), or even partially overlap, and if we want to reduce the size of the module and bring the screen 2 closer to a distance d ₂ < d ₁ we must add light sources 1, and bring them closer to each other (cf. ) which increases the cost. Indeed, the light beams 12 are divergent and to have continuous coverage, it is necessary to increase the number of light sources 1 if the screen 2 is brought closer. The spacing of the light sources depends on the depth of the device. It should be noted that for the clarity of the , the elements of it have been enlarged. Thus, the light sources 1 of Figures 1 and 2 actually have the same dimensions.

In order to have a homogeneous image it is also desirable that the LEDs are distributed uniformly.

The invention offers a solution to the problems mentioned above, by making it possible to limit the number of light sources used while multiplying the secondary light sources in order to limit the distance between the light sources and the screen. By secondary light source we understand, in the present description, an image of the light source through an optical element. So the visual perception is that there are more light sources than the number of light sources actually used in the light module.

1. une première surface d’entrée de lumière en regard de la source lumineuse, dans la direction de l’axe principal X,
2. une première surface de réflexion,
3. une deuxième surface de réflexion,
4. une première surface de sortie de la lumière,

remarquable en ce que la première surface de réflexion est constituée de plusieurs faces concaves et connexes disposées de façon circonférentielle et inclinées par rapport à l’axe principal X, que la deuxième surface de réflexion est constituée de plusieurs faces disposées de façon circonférentielle et inclinées par rapport à l’axe principal X, et en ce que la première surface d’entrée de lumière, la première surface de réflexion, la deuxième surface de réflexion et la première surface de sortie de la lumière sont agencées pour qu’au moins une partie des rayons lumineux émis par la source lumineuse pénètrent dans l’élément optique par la première surface d’entrée de lumière, se réfléchissent successivement sur la première surface de réflexion puis sur la deuxième surface de réflexion, et sortent du module lumineux par la première surface de sortie de la lumière.One aspect of the invention relates to a light module, in particular for a motor vehicle, comprising a light source with a main axis X of light emission, and an optical element, said optical element comprising:

1. a first light entry surface facing the light source, in the direction of the main axis X,
2. a first reflection surface,
3. a second reflection surface,
4. a first light exit surface,

remarkable in that the first reflection surface consists of several concave and connected faces arranged circumferentially and inclined relative to the main axis X, that the second reflection surface consists of several faces arranged circumferentially and inclined by relative to the main axis light rays emitted by the light source enter the optical element via the first light entry surface, are reflected successively on the first reflection surface then on the second reflection surface, and exit the light module via the first surface light output.

This arrangement allows, from a light source, to create one or more secondary light sources, due to this path of the light rays. These secondary light sources are called auxiliary secondary light sources, because they are an offset image of the light source compared to its real position, relative to the main axis X, when the module is observed along this axis.

Having an optical element with a first reflection surface with connected faces makes it possible to reduce its size. By connected, we mean the fact that each face has a side in common with two other faces, thus forming a continuous surface that is substantially conical, that is to say resting on a cone without necessarily following it rigorously. There is therefore surface continuity between any two points on the first reflection surface. As the faces of the first reflection surface are continuous, the bulk is reduced.

The concave nature of these faces prevents the light beams from diverging.

The light module may include one or more of the following features.

Advantageously, the optical element is in one piece.

Advantageously, the faces of the first reflection surface are more inclined relative to the main axis X than the faces of the second reflection surface. This helps reduce clutter even further.

Advantageously, the optical element is made of one or more transparent materials. Transparent means that it is able to transmit the wavelengths of light emitted by the light source.

Advantageously, the optical element is made of a thermoplastic material such as PPMA (polymethyl methacrylate) or PC (polycarbonate).

Advantageously, the concavity of the faces of the first reflection surface is such that the faces are convex, seen from outside the optical element. They are therefore hollow seen from inside the material of the optical element, particularly in the direction of travel of the light rays.

Advantageously, the concavity of the faces of the second reflection surface is such that the faces are convex, seen from outside the optical element. They are therefore hollow seen from inside the material of the optical element, particularly in the direction of travel of the light rays.

Advantageously, the first reflection surface is arranged so that the light rays are reflected on it by total internal reflection.

Advantageously, the second reflection surface is arranged so that the light rays are reflected on it by total internal reflection.

Advantageously, the optical element comprises a second light output surface arranged opposite the light source. The optical element can thus also directly transmit the light beam from the light source. This light exit surface can be flat or curved. It is placed in the center of the first reflection surface. The rays thus transmitted into the optical element solely by refraction, first by the first light entry surface then by the second light exit surface, also form a secondary light source, called the main secondary light source, because it is a direct image of the light source, in particular an image located along the main axis X.

Advantageously, the second light output surface is at the center of the optical element, that is to say centered on the main axis X. The distribution of the luminous flux is thus uniform.

Advantageously each of the faces of the first reflection surface and the second light output surface are arranged to intercept an identical portion of the light flux emitted by the light source.

In a non-limiting embodiment, each face of the first reflection surface has a concave paraboloid portion shape. This paraboloid face makes it possible to reflect and focus the light beam from the light source, unlike for example a flat face which opens the beam. Advantageously, the paraboloid portion has a focus placed on the image of the light source through the input surface (this surface forming a diopter), and its axis is oriented towards the second reflection surface.

In a non-limiting embodiment, each face of the first reflection surface has a concave shape of an ellipsoid portion. Advantageously, the ellipsoid portion has a focus arranged on the image of the light source through the entrance surface. This ellipsoid face allows the light beam from the light source to be reflected and focused.

In a non-limiting embodiment, certain faces of the first reflection surface have a concave shape of a paraboloid portion and other faces of the first reflection surface have a concave shape of an ellipsoid portion

Other concave shapes are also possible for the faces of the first reflection surface: hyperboloid or circular. These forms can apply to some or all of them.

Advantageously, the faces of the first reflection surface are identical. All the beams arriving on the first reflection surface are then reflected in the same way and therefore have the same brightness. Only the direction around the main axis X of the reflected beam is different from one face to the other.

Advantageously, each face of the second reflection surface has a concave shape with a curved portion. This curved shape keeps the light beams parallel.

Advantageously, the faces of the second reflection surface are identical. All beams arriving on the second reflection surface are reflected in the same way and therefore have the same brightness.

Advantageously, the faces of the second reflection surface are distributed alternately on two cones offset axially. We will thus be able to obtain equidistant light beams on the periphery and thus obtain a uniform image.

Advantageously, each face of the first reflection surface is radially, relative to the main axis X, facing one face of the second reflection surface. There are therefore as many faces of the first reflection surface as of the second reflection surface.

Advantageously, the light source presents an emission having a symmetry of revolution around the main axis X.

Advantageously the light source is Lambertian.

Another aspect of the invention relates to a lighting device, in particular for a motor vehicle, comprising a housing, a closing glass and at least one light module according to the invention. Thanks to the invention, the light device is less deep and therefore less bulky, while illuminating the same surface as a light device with more sources but without a light module according to the invention.

Advantageously, the light device is a lighting and/or signaling device, or an interior lighting device for the passenger compartment of the vehicle.

The invention and its various applications will be better understood on reading the following description and examining the accompanying figures.

BRIEF DESCRIPTION OF THE FIGURES

The figures are presented as an indicative and in no way limiting example of the invention.

is a schematic view of light beams from light sources on a screen in a first state of the art.

is a schematic view of light beams from light sources on a screen in a second state of the art.

is a partial top view of a lighting device with three light sources of the state of the art.

is a partial top view of a lighting device according to the invention.

is a top view of an optical element of the .

is a bottom view of an optical element of the .

is a section of the optical element of Figures 5 and 6 with the light source and the light beams.

DETAILED DESCRIPTION

Unless otherwise specified, the same element appearing in different figures presents a unique reference.

In the remainder of the description, we will call "entry", the side through which the light beams enter the light module and "output", that through which they leave it, "upper", the upper part of Figures 1, 2 and 7 and “lower”, the lower part of said figures. Lower therefore qualifies a part of the module proximal to the light source, and higher a part of the module distal to the light source.

Figures 1 and 2 have been described in the technological background.

We can see on the , a light device according to the prior art using three light sources 1, in a direction of observation corresponding to the main axis X. For reasons of clarity, the housing and the glass are not shown, and only the light sources and the screen have been preserved. Each light source emits a light beam 10 to cover the screen 2.

We can see on the , a light device according to the invention, in a direction of observation corresponding to the main axis X. Here again the housing and the glass are not shown. The light device, illustrated , comprises two light sources 1 each associated respectively with an optical element 3. In other words the light device comprises two light modules according to the invention. Of course it could include another number of light modules, for example just one, or a number greater than two, depending on the size of the surface that we wish to illuminate. Thanks to the optical element 3 several light beams, here nine, can be emitted from a single light source: a primary beam 10 in the center and eight secondary beams 11. We call primary beam 10, the light beam arriving directly from the light source 1 through the first light entry surface then the second light exit surface, and secondary beam 11, the reflected beam coming from the same light source 1 but reflected on the first reflection surface then on the second reflection surface. Each light source 1 comprises a main axis to the secondary beams 11.

The optical element 3 is detailed in Figures 5 and 6. It comprises a flat upper face 30 and a hollow part 31 of substantially conical shape. This hollow part 31 is made up of several concave and connected faces 310 of parabolic shape, here eight. Advantageously, the faces 310 each cover an angular sector of 45° around the main axis Other shapes are possible for the faces 310: conical, elliptical, hyperbolic, etc. The hollow part 31 includes at its center a surface 311, flat or convex. The upper face 30 could also be curved.

The lower face of optical element 3, visible , comprises a flat surface 32 in the center, bordered by several inclined faces 33 and 34. The flat surface 32 is arranged facing the light source 1 in the direction of the main axis X. A first series of inclined faces 33 (here four) are arranged on a first cone, a second series of inclined faces 34 (here four) are arranged on a second cone, the two cones are offset axially, that is to say their apex is offset axially along the main axis X, but they have the same angle at the top. These inclined conical faces 33 and 34 alternate on the circumference of the optical element. The conical faces 34 are offset radially with respect to the conical faces 33, in order to have a set of uniformly distributed sources. Indeed, as is visible on the , the secondary auxiliary light sources are distributed regularly along the perimeter of a square, the main secondary light source being in the center of this square.

There shows the light paths of the different light beams 10 and 11. The light source 1 emits a primary beam 10 towards the flat surface 32 which is placed perpendicular to the main axis X of the light source 1. The rays of the primary beam 10 pass through said surface 32 thus constituting the first entry surface 40. Part of the rays exit directly through a second exit surface 42 of the light constituted by the surface 311 placed opposite the light source 1 and in the center of the hollow part 31. In this example, the surface 311 is flat but it could also be curved, this makes it possible to create a divergent beam at an angle different from that created by the light source and with a divergence similar to that of the auxiliary secondary sources.

Another part of the rays of the primary beam 10 are reflected on a first reflection surface 41 constituted by one of the concave faces 310 of the hollow part 31. They are then reflected on a second reflection surface 43 constituted by one of the inclined faces 33 or 34. The rays then exit the optical element 3 via a first light exit surface 44 constituted by the flat upper face 30.

Due to their curved shape, the different reflection faces make it possible to obtain a secondary beam 11 identical to that which would be obtained with a direct light source. Thanks to the invention we obtain the equivalent of several auxiliary secondary light sources (here 8) with a single source.

Thus, in a light device it is possible to use a reduced number of light sources while maintaining a low depth, the space between the light sources being filled by the presence of secondary sources, in particular auxiliary secondary sources.

It is possible to superimpose several optical elements to further multiply the light sources.

Claims (11)

Light module, in particular for a motor vehicle comprising a light source (1) of main axis X of light emission and an optical element (3), said optical element comprising:

• a first light entry surface (40) facing the light source (1), in the direction of the main axis X,
• a first reflection surface (41),
• a second reflection surface (43),
• a first light exit surface (44),

characterized in that the first reflection surface (41) consists of several concave and connected faces (310) arranged circumferentially and inclined relative to the main axis X, that the second reflection surface (43) consists of several faces (33, 34) arranged circumferentially and inclined relative to the main axis reflection (43) and the first light exit surface (44) are arranged so that at least part of the light rays emitted by the light source enter the optical element via the first light entrance surface ( 40), are reflected successively on the first reflection surface (41) then on the second reflection surface (43), and exit the light module via the first light exit surface (44). Light module according to claim 1, characterized in that the optical element (3) comprises a second light output surface (42) arranged opposite the light source (1). Light module according to the preceding claim, characterized in that the second light output surface (42) is in the center of the optical element (3). Light module according to one of the preceding claims, characterized in that each face (310) of the first reflection surface (41) has a concave paraboloid portion shape. Light module according to one of claims 1 to 3, characterized in that each face (310) of the first reflection surface (41) has a concave shape with an ellipsoid portion. Light module according to one of the preceding claims, characterized in that the faces (310) of the first reflection surface (41) are identical. Light module according to one of the preceding claims, characterized in that each face (33, 34) of the second reflection surface (43) has a concave shape with a curved portion. Light module according to one of the preceding claims, characterized in that the faces (33, 34) of the second reflection surface (43) are identical. Light module according to one of the preceding claims, characterized in that the faces (33, 34) of the second reflection surface (43) are distributed alternately over two axially offset cones. Light module according to one of the preceding claims, characterized in that each face (310) of the first reflection surface (41) is radially, relative to the main axis , 34) of the second reflection surface (43). Lighting device comprising a housing, a closing glass and at least one light module according to one of the preceding claims.