LIGHT DEVICE, ESPECIALLY A SIGNAL LAMP, FOR A MOTOR VEHICLE

Abstract

The light device comprises an optical module (17), comprising a light source (5) and an associated optical body (8) of a transparent material to bind light rays (10) emitted by the source (5). The source (5) is a multidirectional light source configured to emit the primary light beam (6) of rays (10) towards the cover (1), and secondary beams (7) comprising rays (10) that are approximately transversal with respect to the rays (10) of the primary beam (6). The body (8) has a front surface (12) that forms a central front recess (18) in the body (8), a rear surface (14) that is opposite to the front surface (12) and is, in the direction from the optical axis (x) of the optical module (17), which passes through the source (5), inclined towards the cover (1), and a lateral surface (13) connecting the front surface (12) with the rear surface (14). The deepest point of the front recess (18) is situated approximately at the optical axis (x). The rear surface (14) and the lateral surface (13) are configured to prevent rays (10) from passing through these surfaces (14, 13).

Claims

1. A light device for a motor vehicle, comprising an outer cover separating the inner chamber of the light device from the external environment of the motor vehicle, and at least one optical module situated in the chamber comprising a light source and an associated optical body of a transparent or translucent material, the optical body being designed to bind light rays) emitted by the source and to enable passage of rays through the optical body and their exit from the optical body towards the cover, wherein the source is a multidirectional light source configured to emit the primary light beam of rays towards the cover, and secondary beams comprising rays that are approximately transversal with respect to the rays of the primary beam, the optical body having a front surface that is situated between the cover and source and forms a central front recess in the optical body extending over most of the front surface, wherein the optical body comprises: a rear surface that is opposite to the front surface and is, in the direction from the optical axis (x) of the optical module, which optical axis (x) passes through the source, inclined towards the cover, and a lateral surface connecting the front surface with the rear surface, wherein the deepest point of the front recess is situated approximately at the optical axis (x), wherein the front surface is configured to reflect a part of rays of the primary beam towards the rear surface and to enable passage of another part of rays of the primary beam through the front surface out of the optical body in a direction towards the cover, wherein the front surface is further configured for passage of rays that got reflected from the lateral surface or the rear surface before falling onto the front surface, through the front surface out of the optical body towards the cover, wherein the rear surface is configured to reflect rays falling onto it directly or indirectly by means of subsequent reflection from the lateral surface to the front surface, wherein the lateral surface is configured to reflect rays falling onto it to the front surface or the rear surface, wherein the rear surface and the lateral surface are configured to prevent rays from passing through these surfaces.

2. The light device according to claim 1, wherein the lateral and rear surfaces are configured as mirror surfaces.

3. The light device according to claim 1, wherein the lateral and rear surfaces are fitted with a reflective layer, such as a mirror layer, diffusion reflective layer, or a white reflective layer.

4. The light device according to claim 1, wherein the central front recess and the rear surface are part of approximately conical surfaces having their apices lying approximately at the optical axis (x).

5. The light device according to claim 1, wherein the optical body comprises a rear recess surrounded by the rear surface, and the source is situated in the rear recess.

6. The light device according to claim 1, wherein the source is in contact with the optical body.

7. The light device according to claim 1, wherein the source is embedded in the material of the optical body.

8. The light device according to claim 1, wherein the source is attached to a thin-walled carrier, the optical body being situated between the carrier and the cover.

9. The light device according to claim 8, wherein at least a part of the rear surface of the body is situated at a distance from the thin-walled carrier.

10. The light device according to claim 8, wherein the thin-walled carrier is shaped in such a way that the entire rear surface and/or lateral surface of the body is in contact with the thin-walled carrier.

11. The light device according to claim 10, wherein the thin-walled carrier is configured in such a way that the carrier wall in the locations where the carrier is in contact with the rear surface and/or lateral surface forms a reflective layer that the rear surface and/or the lateral surface of the body is equipped with.

12. The light device according to claim 8, wherein the thin-walled carrier is shaped in such a way that a recess is formed in it whose shape corresponds to the shape of the optical body, the optical body being a casting located in this recess.

13. The light device according to claim 8, wherein the carrier is foil.

14. The light device according to claim 1, wherein the light device comprises a number of optical modules, the sources being attached to a common thin-walled carrier.

15. The light device according to claim 14, wherein at least a part of the rear surface of the optical body is situated at a distance from the thin-walled carrier, and the optical bodies are carried by an optical board situated against the thin-walled carrier.

16. The light device according to claim 14, wherein between the front surfaces of the optical bodies and the cover, a functional layer is situated approximately in parallel to the cover and configured to direct light rays that exit from its surface averted from the optical body to a predetermined direction or directions and/or to homogenize the light rays.

17. The light device according to claim 14, wherein the cover comprises a filter adapted for diffusion/homogenization and/or directing of rays passing through the cover.

Description

CLARIFICATION OF DRAWINGS

[0021] The invention will be clarified in a more detailed way with the use of embodiment examples with references to attached drawings, where:

[0022] FIG. 1 shows in an exploded view the first embodiment example of the light device according to the invention,

[0023] FIG. 2 shows a vertical cross-section of the first embodiment example of the light device, taken through the optical axis of one of the optical modules contained in the light device,

[0024] FIG. 3 shows the front view of the first embodiment example of the light device,

[0025] FIG. 4 shows a vertical cross-section of the second embodiment example of the inventive light device, taken through the optical axis of one of the optical modules contained in the light device, and

[0026] FIG. 5 shows a vertical cross-section of the third embodiment example of the inventive light device, taken through the optical axis of one of the optical modules contained in the light device.

EXAMPLES OF EMBODIMENTS OF THE INVENTION

[0027] FIGS. 1 to 3 show various views of the first embodiment example of the light device according to the invention.

[0028] FIG. 1 shows the light device in an exploded view. The light device comprises a carrier plate 2 intended to be attached to the front cover 1, which is transparent or translucent in at least some of its regions. The cover 1 and the carrier plate 2 delimit an inner chamber 3 between them. The carrier plate 2 is fitted with locating protrusions 22 at its inner side. A thin-walled carrier 16 carrying the light sources 5, an optical board 4 comprising optical bodies 8 and a functional layer 9 are situated between the carrier plate 2 and the cover 1, starting from the carrier plate 2. The locating protrusions 22 pass through the respective openings in the thin-walled carrier 16, optical plate 4 and functional layer 9 and delimit their mutual position. Thus, the light device is delimited at its rear side by the carrier plate 2 that the translucent or transparent cover 1 is attached to in such a way that the carrier plate 2 and the cover 1 define the inner chamber 3 of the light device between them. During the operation of the light device installed in a vehicle, the cover 1 is, with its outer side, in contact with the surrounding environment that is found outside the vehicle.

[0029] FIG. 2 shows a vertical cross-section of the first embodiment example of the light device in the assembled condition, taken through the optical axis x of one of the optical modules 17 contained in the light device. The optical axis x of the optical module 17 is generally an axis of an overall light beam comprised of light rays leaving an output front surface 12 of the optical module 17. One or more optical modules 17 can be housed in the chamber 3. The embodiment shown in FIGS. 1 to 3 presents an example in which light device comprises a number of optical modules 17 situated next to each other. As shown in FIG. 2, each optical module 17 comprises a light source 5 to generate light rays 10 and an optical body 8 the light source 5 is associated with. At the same time, the light source 5 may comprise one or more LED's or chips situated close to each other. The light source 5 is a multidirectional source configured to generate the primary light beam 6 of light rays 10 towards the cover 1, and at least one secondary light beam 7 comprising light rays 10 that are approximately transversal to the rays 10 of the primary beam 6. The light source 5 may be configured to emit one or more secondary beams 7 whose axes generally lie on a plane that is perpendicular to the optical axis x of the optical module 17 and passes through the source 5. In the particular embodiment of FIG. 2, the light source 5 emits secondary beams 7 to all sides approximately transversally to the optical axis x though only one secondary beam 7 is shown in FIG. 2 for simplicity. As mentioned above, the optical module 17 comprises an optical body 8 of a translucent or transparent material, configured to bind light rays 10 emitted by the source 5 to the body 8, to guide the rays 10 through the body 8, and finally to ensure their exit from the body 8 through its front surface 12 towards the cover 1. The shape of the front surface 12 is such that it forms a front recess 18 in the body 8, which may for instance have a conical shape. The front surface 12 is situated between the cover 1 and the source 5. Further, the body 8 is delimited by its rear surface 14, which is opposite to the front surface 12, and the lateral surface 13 connecting the front surface 12 with the rear surface 14. In the embodiment shown, the front surface 12 and rear surface 14 are part of approximately conical surfaces with apices lying approximately at the optical axis x of the optical module 17, which passes through the source 5. As mentioned above, however, the front recess 18 does not necessarily have to be of a conical shape, other than conical shapes are also possible, e.g. a generally dish-like shape, the shape of an optical lens (e.g. ball-shaped) etc.

[0030] The body 8 comprises entry areas 11 adapted to bind the light rays 10 of the primary beam 6 and the secondary beams 7 and defining the rear recess 19 in the body 8. As shown in FIG. 2, the front surface 12 is configured for total reflection of a part of the rays 10 of the primary beam 6 towards the rear surface 14 while another part of the rays 10 of the primary beam 6 that fall onto the front surface 12 under a smaller angle than the critical angle, i.e. under an angle that enables passage through the front surface 12, passes through the front surface 12 out of the body 8 towards the cover 1. Light rays 10 that got reflected from the rear wall 14 or the lateral wall 13 before falling onto the front surface 12 also pass through the front surface 12 out of the body 8 towards the cover 1. The rear surface 14 is configured for direct, or also possibly by means of subsequent reflection from the lateral surface 13, indirect reflection of rays 10 falling onto it towards the front surface 12. The lateral surface 13 and the rear surface 14 are configured to prevent exit of light rays 10 out of the body 8 through these surfaces 13, 14. The reflection of rays 10 from the lateral surface 13 and the rear surface 14 may for instance be based on the principle of total reflection (on condition that this will satisfactorily meet the requirement of preventing exit of light rays 10 out of the body 8 through these surfaces 13, 14), however, these surfaces may be fitted with a reflective layer 20 as in the embodiment shown. The reflective layer 20 may e.g. be a mirror or diffusion one. If it is a diffusion layer, it is preferably a layer 20 of white color.

[0031] As shown in FIGS. 1 and 2, the rays 10 that have passed through the front surface 12 out of the body 8 towards the cover 1 fall onto a functional layer 9, configured to homogenize and/or direct light rays 10 that exit from the surface of the functional layer 9 averted from the body 8 to a predetermined direction or directions. As indicated in FIG. 2 and FIG. 3, the front cover 1 of this embodiment comprises a segment or filter 15 configured for diffusion of light rays 10 passing through the front cover 1 and/or for their directing.

[0032] FIG. 4 shows the second example of an embodiment of the light device according to the invention. Similarly to FIG. 2, this is also a vertical cross-section of the light device, taken through the optical axis x of one of the optical modules contained in the light device. However, this embodiment differs from the embodiment of FIGS. 1 to 3 especially in that the thin-walled carrier 16 is spatially shaped in such a way that the lateral surface 13 and the rear surface 14 of the optical bodies 8 bear on the inner surface of the thin-walled carrier 16. Thus, the optical board 4 and the thin-walled carrier 16 are in mutual contact in the locations of the rear surfaces 14 and the inner surface of the thin-walled carrier 16 in these locations serves as a reflective surface for light rays 10 falling onto the rear surface 14. The production process of this second embodiment of the invention is such that the thin-walled carrier 16 in the form of flexible foil of preferably white color is fitted with the respective electronic equipment (light sources 5 and conductive paths, driver etc.), subsequently, the thin-walled carrier 16 is placed in a mold, 3D shaped and then the optical board 4 comprising optical bodies 8 is added to it by injection. In the second embodiment of the invention, there is no air gap between the optical board 4 and the thin-walled carrier 16 unlike the first embodiment.

[0033] FIG. 5 shows the third example of an embodiment of the light device according to the invention. This is also a vertical cross-section of the light device, taken through the optical axis x of one of the optical modules 17 contained in the light device. However, this embodiment differs from the previous embodiments of FIGS. 1 to 4 in that the shape of the front surface 12 is such that it forms a front recess 18 in the body 8 having the shape of an optical lens, e.g. a ball-shaped one.

LIST OF REFERENCE MARKS

[0034] 1—front cover [0035] 2—carrier plate [0036] 3—chamber [0037] 4—optical board [0038] 5—source [0039] 6—primary beam [0040] 7—secondary beam [0041] 8—optical body [0042] 9—functional layer [0043] 10—ray [0044] 11—entry area [0045] 12—front surface [0046] 13—lateral surface [0047] 14—rear surface [0048] 15—filter [0049] 16—thin-walled carrier [0050] 17—optical module [0051] 18—front recess [0052] 19—rear recess [0053] 20—reflective layer [0054] 22—locating protrusions [0055] X—optical axis