LIGHT-GUIDING OPTICAL SYSTEM, ESPECIALLY FOR MOTOR VEHICLES

Abstract

The light-guiding optical system comprises at least one light source (2) and a light guide (1) for coupling and guiding light rays (10) emitted by a light source (2). Furthermore, the light guide (1) may comprise a decoupling surface (4) on its rear side (13) and an output surface (3) for the exit of light rays (10) decoupled by the decoupling surface (4) on an opposite front side (14). The decoupling surface (4) comprises: (i) first decoupling elements (5) configured to decouple light rays (10) falling onto the first decoupling elements (5) out of the light guide (1) approximately in a pre-determined first output direction (p) to fulfill a first light function, and (ii) a second decoupling element (6) configured to uncouple light rays (10) falling onto the second decoupling elements (6) out of the light guide (1) approximately in a pre-determined second output direction (d), which is deflected from the first output direction (p), to fulfill the second light function.

Claims

1. A light-guiding optical system for motor vehicles comprising at least one light source and a light guide for coupling and guiding light rays (10) emitted by the light source, wherein the light guide comprises a decoupling surface on a rear side of the light guide and an output surface for an exit of light rays decoupled by the decoupling surface on an opposite front side of the light guide, wherein the decoupling surface comprises first decoupling elements configured to decouple the light rays falling onto the first decoupling elements out of the light guide approximately in a pre-determined first output direction to fulfill a first light function and a second decoupling element configured to decouple the light rays falling onto the second decoupling element out of the light guide approximately in a pre-determined second output direction diverted from the first output direction to fulfill a second light function.

2. The light-guiding optical system according to claim 1, wherein the light guide has an elongated shape, wherein the decoupling surface and the output surface are positioned in a longitudinal direction of the light guide.

3. The light-guiding optical system according to claim 1, wherein the first decoupling element is a first reflective surface which is inclined towards the output surface in a direction from the light source and is configured for reflection of the light rays falling onto the first reflective surface directly to the output surface and incidence of the light rays on the output surface at an angle excluding total reflection, so that the light rays exit from the light guide through the output surface approximately in the first output direction.

4. The light-guiding optical system according to claim 1, wherein the second decoupling element is a pair of reflective surfaces comprising a second reflective surface and a third reflective surface that together form an obtuse angle and are configured for reflection of the light rays that fell on the second reflective surface, directly onto the third reflective surface, and a consecutive reflection of the light rays from the third reflective surface directly to the output surface and incidence of the light rays on the output surface at an angle excluding a total reflection, so that these light rays exit from the light guide through the output surface approximately in the second direction.

5. The light-guiding optical system according to claim 4, wherein in a direction from the light source, the second reflective surface is situated in a direct extension of the first reflective surface and a positional order in a direction from the light source is the first reflective surface, the second reflective surface and the third reflective surface.

6. The light-guiding optical system according to claim 4, wherein the first reflective surface and the second reflective surface are connected to each other.

7. The light-guiding optical system according to claim 4, wherein the second reflective surface and the third reflective surface are connected along a connecting line.

8. The light-guiding optical system according to claim 4, wherein the decoupling surface further comprises a fourth reflective surface configured for reflection of the light rays falling onto the fourth reflective surface, directly towards the output surface and incidence of the light rays) on the output surface at an angle, which will cause total reflection of the light rays from the output surface and further propagation of the light rays through the light guide, wherein the first reflective surface, the second reflective surface, the third reflective surface and the fourth reflective surface are in a positional order from the light source and are part of a reflective arrangement) that repeats itself in a longitudinal direction on the decoupling surface.

9. The light-guiding optical system according to claim 8, wherein the fourth reflective surface is approximately parallel to an opposite part of the output surface.

10. The light-guiding optical system according to claim 8, wherein the connecting line lies on a hypothetical surface that is a direct extension, in the direction towards the light source, of the fourth reflective surface.

11. The light-guiding optical system according to claim 8, wherein the light guide comprises a plurality of reflective arrangements, wherein lengths of the reflective arrangements are identical.

12. The light-guiding optical system according to claim 8, wherein the light guide comprises at least two reflective arrangements having different lengths in order to achieve the required resulting appearance and homogeneity.

13. The light-guiding optical system according to claim 8, wherein length of the reflective arrangement is approximately from 0.7 mm to 3.5 mm.

14. The light-guiding optical system according to 4, wherein the second reflective surface makes an angle from 95 to 150 with the third reflective surface.

15. The light-guiding optical system according to claim 1, wherein the first light function is a function of a tail light and the second light function is a function of a side clearance light.

16. The light-guiding optical system according to claim 1, wherein the first output direction makes an angle of approximately 90 with the second output direction and is approximately parallel to a longitudinal axis of a vehicle.

17. The light-guiding optical system according to claim 1, wherein the first light function is a function of a back-up lamp and the second light function is a function of specific points for a camera.

Description

CLARIFICATION OF DRAWINGS

[0023] The present invention will be further clarified in more detail with the use of embodiment examples referring to the enclosed drawings where:

[0024] FIG. 1 shows, in a top view, an embodiment example of a light-guiding optical system according to the invention,

[0025] FIG. 2 shows, in a longitudinal cross-section through the longitudinal axis of the invention of FIG. 1, an embodiment example of the decoupling surface of the optical system according to the invention,

[0026] FIG. 3 shows, in a longitudinal cross-section through the longitudinal axis of the invention of FIG. 1, an embodiment example of the reflective surfaces of the reflective assembly of the optical system according to the invention, and

[0027] FIGS. 4 to 6 show the courses of light rays falling onto individual reflective surfaces of the optical system according to the invention.

EXAMPLES OF EMBODIMENTS OF THE INVENTION

[0028] FIG. 1 shows, in a top view, an embodiment example of a light-guiding optical system according to the invention. The light-guiding optical system comprises a light source 2 to emit light rays 10 and a light guide 1. The light guide 1 has a rod-like shape and the light source 2 is situated at one of the ends of the light guide 1. Light rays 10 are bound to the light guide 1 and proceed through it in the direction from the light source 2.

[0029] The light guide 1 is fitted, on its rear side 13, with an decoupling surface 4 configured to direct light rays 10 to the output surface 3 positioned on the front side 14 of the light guide 1 and also to make sure that the light rays 10 that, on incidence on the output surface 3, did not exit from the light guide 1 through this surface 3, proceed further through the light guide 1 in the direction from the light source 2. In this embodiment, the decoupling surface 4 is configured for two light functions. For the first light function, light rays 10 are directed with a certain diffusion approximately in a pre-defined first output direction p, which is advantageously parallel to the longitudinal axis of the vehicle. For the second light function, light rays 10 are directed with certain diffusion approximately in the pre-defined second output direction d, the first output direction p and the second output direction d preferably making approximately an angle of 90, but in other embodiments they may also make a different angle, especially an acute angle. An example of the first light function is the function of the rear tail light and of the second light function the function of a side clearance light.

[0030] FIG. 2 shows, in a longitudinal cross-section through the longitudinal axis of the invention of FIG. 1, an embodiment example of the decoupling surface 4. The decoupling surface 4 comprises the first decoupling elements 5 configured to direct light rays 10 to the output surface 3 in the direction where light rays 10 fall onto the output surface 3 at the angle of incidence 5, measured to the vertical line to the output surface 3 in the place of incidence, ensuring exit of light rays 10 from the output surface 3 approximately in the said first output direction p to guarantee fulfillment of the first light function. The angle of incidence 5 must be such as to exclude total reflection on the output surface 3.

[0031] As it is commonly known, on the surfaces that represent transition from one environment to another environment, depending on the refractive index of both the environments and on the value of the angle of incidence of rays on the surface, either refraction occurs on this surface, the rays entering one environment from the other, or a total reflection on the surface occurs, the ray further moving in the original environment, not entering the other environment.

[0032] Known relationships generally indicate that the angle of incidence 5 must be smaller than a certain critical angle determined by the refraction indices of the light guide 1 and the environment outside the output surface 3 so that the light rays 10 can pass through the output surface 3.

[0033] The decoupling surface 4 further comprises the second decoupling elements 6 configured to direct light rays 10 to the output surface 3 in such a way that the light rays 10 fall onto the output surface 3 at the angle of incidence 6, ensuring exit of light rays 10 from the output surface 3 approximately in the pre-defined output direction d to guarantee fulfillment of the second light function. As explained, the angle 6 must be smaller than the above-mentioned critical angle.

[0034] The decoupling surface 4 further comprises a reflective element in the form of the fourth reflective surface 12, which is configured to direct light rays 10 towards the output surface 3 in such a way that light rays 10 fall onto it at the angle of incidence 12, which is bigger than the above-mentioned critical angle so that these light rays 10 get totally reflected on the output surface 3 and the rays 10 proceed further through the light guide 1.

[0035] FIG. 3 shows an embodiment example of the first decoupling element 5, the second decoupling element 6 and the fourth reflective surface 12, which are together part of the reflective arrangement 11 that is part of the decoupling surface 4. In this embodiment, the reflective arrangement 11 comprises the first decoupling element 5, the second decoupling element 6 and the fourth reflective surface 12 in this order from the light source 2. The first decoupling element 5 comprises the first reflective surface 7 that is, in the direction towards the light source 2, deflected from the opposite output surface 3 by the angle . Light rays 10 falling onto the first reflective surface 7 are reflected directly to the output surface 3, which they fall onto in such a way that they exit from it in the pre-defined first output direction p. The second decoupling element 6 comprises the second reflective surface 8 and the third reflective surface 9, which are preferably connected to each other, are oriented towards each other at an obtuse angle , and are configured for reflection of light rays 10 falling onto the second reflective surface 8 directly onto the third reflective surface 9 and their reflection from the third reflective surface 9 directly to the output surface 3 and incidence on the output surface 3 at an angle excluding total reflection so that these light rays 10 exit from the light guide 1 through the output surface 3 approximately in the said second output direction d.

[0036] In the direction from the light source 2, the second reflective surface 8 is preferably situated in a direct extension of the first reflective surface 7. Further, the first reflective surface 7 and the second reflective surface 8 are preferably connected to each other.

[0037] In the embodiment shown in FIG. 3, the fourth reflective surface 12 and the connecting line s where the second reflective surface 8 gets in contact with the third reflective surface 9 lie on the central jacket surface 17 of the light guide 1. The central jacket surface 17 refers to a smooth surface without the projections and recesses formed by the first and second decoupling elements 5 and 6, which forms the surface of the light guide on its rear side 13 except for the said projections and recesses. The first set-off surface 15 then connects the fourth reflective surface 12 of the previous reflective arrangement 11 to the first reflective surface 7 of the next reflective arrangement 11. In each reflective arrangement 11, the second set-off surface 16 connects the third reflective surface 9 to the fourth reflective surface 12.

[0038] FIGS. 4 and 5 show similar courses of light rays 10 falling onto the first and second reflective elements 5, 6, and FIG. 6 then shows the course of light rays that fall onto the fourth reflective surface 12.

[0039] It should be noted that FIGS. 1 to 6 are not drawn in the proportional scale of the real embodiment of the light guide 1 fitted with a decoupling surface 4 with a reflective arrangement 11 according to the present invention. This is because compared to the real distance from the decoupling surface 4 to the output surface 3, which may be e.g. from 6 mm to 12 mm, the exemplary length of the reflective arrangement 11 measured in the longitudinal direction of the light guide 1 is in the range from 0.7 mm to 3.5 mm Therefore, the geometrical proportions cannot be drawn in the proportional scale for clarification purposes.

[0040] It is also obvious that the boundaries where individual reflective surfaces 7, 8, 9 and 12 begin and stop fulfilling their designed functionsi.e. directing rays for the output in a certain direction, or in the case of the fourth reflective surface 12 for total reflection from the output surface 3cannot be exactly defined. What may happen in practice is that, e.g. in the place of transition from the first reflective surface 7 to the second reflective surface 8, there will be a certain mixed area where, depending on the exact angle of incidence of light rays 10 on this area, light rays 10 may be routed to both the directions p and d. Also, the beginning of the fourth reflective surface 12, i.e. the place from where on in the direction from the light source 2 light rays 10 will be reflected in such a way to fall onto the output surface 3 at an angle 12 bigger than the critical angle discussed above, will not be situated exactly in the place of connection to the second set-off surface 16 where in fact a microscopical area may be in shade caused by the vertex of the second decoupling element 6 or the end of the third reflective surface 9. Similarly, in practice, the first reflective surface 5 will not start at the place of connection to the first set-off surface 15 because a certain small area near this connection will be in shade caused by the vertex resulting from the connection of the fourth reflective surface 12 of the previous reflective arrangement 11 with the first set-off surface 15, which prevents light rays 10 from falling onto this area to be reflected as it is desired for the first decoupling element 5, i.e. the first reflective surface 7, directly to the output surface 3 and from there out of the light guide 1 in the first output direction p.

[0041] Lengths L of individual complex reflective arrangements 11, the same light guide 1 is equipped with, may be identical and/or at least two of the reflective arrangements 11, the same light guide 1 is equipped with, have different lengths L to achieve the required resulting effect or homogeneity. In other words, the required resulting appearance or homogeneity of the light image(s) produced by the light guide 1 can be achieved by suitable selection of lengths L of individual complex reflective arrangements 11 or the appearance can be significantly influenced.

LIST OF REFERENCE MARKS

[0042] 1light guide [0043] 2light source [0044] 3output surface [0045] 4decoupling surface [0046] 5first decoupling element [0047] 6second decoupling element [0048] 7first reflective surface [0049] 8second reflective surface [0050] 9third reflective surface [0051] 10light ray [0052] 11reflective arrangement [0053] 12fourth reflective surface [0054] 13rear side [0055] 14front side [0056] 15first set-off surface [0057] 16second set-off surface [0058] 17central jacket surface [0059] , 5, 6, 12, angle [0060] pfirst output direction [0061] dsecond output direction [0062] sconnecting line